Pump assembly

A pump assembly for use in fire fighting service is constructed of a single stage main pump and a two stage booster pump connected in series with the discharge of the main pump being connected to a first high flow rate fire fighting application and to the inlet of the booster pump and the discharge of the booster pump being connected to a second low flow high pressure fire fighting application. The impellers for both the main pump and the booster pump are mounted on a common rotating shaft so as to be driven thereby. A flow restriction and conduit means is provided to reduce the pressure on the booster pump seal. A by-pass conduit is arranged to conduct flow from the discharge of the booster pump back to the inlet of the main pump so that whenever the main pump is operated there will be flow through the booster pump to prevent overheating thereof.

BACKGROUND AND SUMMARY OF THE INVENTION 
In the field of fire fighting there is a need for a pump assembly for a 
fire truck which is capable of delivering water at a first pressure to a 
first high flow rate fire fighting application, such as a 21/2 inch 
discharge fire hose, and to deliver water at a second pressure 
(substantially higher than said first pressure) to a second low flow high 
pressure fire fighting application, such as a booster pump reel. 
In accordance with the invention there is provided a pump assembly of the 
indicated type that is inexpensive to construct, easy to operate and 
reliable. To this end, the pump assembly in accordance with the invention 
is provided with a main pump and a booster pump connected in series with 
the discharge of the main pump being delivered to a first high flow rate 
fire fighting application and to the inlet of the booster pump and the 
discharge of the booster pump being delivered to a second low flow high 
pressure fire fighting application. The impellers for both the main pump 
and the booster pump are mounted on a common rotating shaft so as to be 
driven thereby. In accordance with another feature of the invention a 
means are provided to reduce the pressure on the booster pump seal. In 
accordance with still another feature of the invention a by-pass conduit 
is arranged to conduct flow from the discharge of the booster pump back to 
the inlet of the main pump so that whenever the main pump is operated 
there will be flow through the booster pump to prevent overheating 
thereof. 
The pump assembly of the invention involves simplicity and speed of 
operation. Both the booster pump and the main pump always operate together 
permitting the firemen to operate either the first or second fire fighting 
application or both of them together. Typically, the booster pump is 
connected to a booster pump line which is wrapped on a "live" reel and 
connected to a fog nozzle, and is usually placed into service as soon as 
possible when the fire truck arrives at the site of a fire and is supplied 
from a tank carried on the fire truck. It takes a high pressure to 
overcome friction of the booster reel's small diameter hose which uses a 
relatively small flow of water and can only operate for limited periods of 
time to dispense the tank water efficiently onto the fire. Maximum cooling 
effect or water vaporization can be achieved by the small volume booster 
fire stream if the stream is broken up into very fine particles through a 
fog nozzle. Also, since the reel's hose is much smaller and lighter than 
the 21/2 inch discharge hoses, it can be handled more easily and placed 
into service much more quickly. By reason of the construction of the pump 
assembly in accordance with the invention, the firemen can place in 
operation the main pump that supplies the 21/2 inch discharge hoses easily 
and without delay. This is achieved by simply opening the discharge valve 
to which the 21/2 inch discharge fire hose has been connected and without 
making any changes in the operation of the pump assembly or opening and 
closing a number of valves. Thus, the first and second fire fighting 
applications are performed concurrently and speedily. There is no need to 
slow down the drive to permit disengagement of the booster pump and 
engagement of the main pump as is the case with most types of fire 
fighting equipment in use today in which the booster pump and the main 
pump are driven by independent means. Thus, the prior art equipment 
involves a substantial time delay as compared with the pump assembly in 
accordance with the invention. 
Another type of prior art pump assembly that has been used is designed to 
achieve the high pressure necessary to operate a booster reel by providing 
two impellers and means for operating the impellers in either series or 
parallel, the higher pressure operation being achieved by arranging the 
impellers in series. The discharge passage of this type of pump has 
available either high pressure low volume water in series or low pressure 
high volume water in parallel, but not both. Thus, such a pump cannot 
operate at two pressure levels unless an intermediate discharge from the 
first stage is provided, but this requires separate and expensive piping. 
In accordance with another prior art pump assembly a third impeller is 
clutched onto the impeller shaft of a two stage pump and is connected to a 
low flow and high pressure application. However, this arrangement is 
unsatisfactory because it involves a high pressure seal at the third stage 
inlet, which high pressure seal is subject to excessive wear and premature 
failure. Additionally, the clutch is a source of mechanical problems, 
added expense and the pump has to be slowed down to engage and disengage 
the clutch. 
Another feature of the pump assembly of the invention is that it is 
hydraulically engineered to provide the optimum hydraulic design for the 
impellers of both the main pump and the booster pump. This is not possible 
with the prior art pumps discussed above. In the typical series-parallel 
pump, the impellers are designed for much higher flow rates than would be 
handled by a booster line. For example, a series-parallel pump designed to 
operate at a flow rate of 1000 G.P.M. in the series arrangement, is 
designed so that each impeller handles 500 G.P.M. However, an impeller 
designed to handle 500 G.P.M. is not at all efficient when handling 30-50 
G.P.M., which is the flow rate for a typical booster line application. In 
the pump assembly of the invention there is used a two stage booster pump 
having a small impeller diameter specifically designed for booster line 
applications. Such an impeller has a substantially lower power requirement 
as compared with the large diameter impellers of the prior art. Also, by 
reason of the small impeller diameter of the booster pump, there is very 
little drag (friction loss) on the main pump when the booster pump is not 
in use. 
An additional feature of the pump assembly in accordance with this 
invention is that it can be retrofitted to existing fire trucks easily and 
can utilize previously available pump designs for both the booster pump 
and the main pump with minor modifications.

DESCRIPTION OF THE PREFERRED EMBODIMENT 
The pump assembly in accordance with the invention comprises a main pump 10 
of the centrifugal type having an inlet provided by a pair of inlet tubes 
12 constructed and arranged to be connected to a water supply from either 
side of a fire truck and communicating with inlet chambers 14 at the 
entrance to the single stage double suction impeller 16. The exit 18 from 
the impeller 16 communicates with a main pump discharge passage 20 which 
communicates with discharge valves 22 adapted to be connected to a first, 
high flow rate, fire fighting application, typically a 21/2 inch discharge 
fire hose. 
The pump assembly also comprises a booster pump 30 of the centrifugal type 
having an inlet provided by an inlet passage 32 communicating at its 
downstream end with an inlet chamber 34 at the entrance to the first stage 
impeller 36 of a two stage impeller means for the booster pump 30. The 
exit from the first stage impeller 36 is connected to the entrance of a 
second stage impeller 38 by means of a U-shaped cross-over tube 40. The 
exit from second stage impeller 38 is in communication with a discharge 
tube 42 connected to a discharge valve 44 adapted to be connected to a 
second, low flow high pressure, fire fighting application, typically, a 
booster hose line coiled on a "live" booster reel. 
Means are provided for connecting the discharge from main pump 10 to the 
suction of booster pump 30. To this end, a pipe conduit 48 is connected 
between a fitting 24, which communicates with discharge passage 20, and 
inlet passage 32. Pipe conduit 48 delivers water from the discharge of 
main pump 10 to the inlet of booster pump 30. 
Means are provided for communicating flow from the discharge of booster 
pump 30 back to the inlet of main pump 10. To this end, a by-pass conduit 
49 is connected from discharge tube 42 back to the main pump suction at 
inlet chamber 14. By-pass conduit 49 is always open to flow so that 
circulation of flow is maintained through booster pump 30 anytime main 
pump 10 is operated whether valve member 44 is open or closed. This flow 
prevents overheating of booster pump 30. 
In accordance with the invention, there is provided impeller drive means 
for main pump 10 and booster pump 30 comprising a common rotating pump 
shaft 50. Shaft 50 is rotatably supported by bearings in a drive unit 
housing 52 and extends in both directions therefrom. Referring to FIG. 2, 
the portion of shaft 50 extending to the left of housing 52 has impeller 
16 drivingly mounted thereon by means of a key 54 and the portion of shaft 
50 extending to the right from housing 52 has impellers 36 and 38 of 
booster pump 30 drivingly mounted thereon by means of a key 56. 
The portion of shaft 50 within housing 52 has a gear 58 keyed thereon for 
causing rotation of shaft 50. Gear 58 is driven by means of an 
intermediate gear 60 which is, in turn, driven by a sliding gear 62. 
Sliding gear 62 is constructed and arranged to be driven from the 
transmission of the fire truck and is conventional and well known in the 
art. 
In accordance with a feature of the invention, a seal means is provided to 
reduce the pressure at the seal at inlet to booster pump 30 to a pressure 
approximating that of the main pump suction. To this end, an adapter 70, 
which forms part of the housing of booster pump 30 and mounts booster pump 
30 onto drive unit housing 52, defines a chamber 72 surrounding pump shaft 
50 at a location adjacent inlet chamber 34. A mechanical seal means is 
provided between shaft 50 and adapter 70 to prevent the flow of water from 
chamber 72 to the exterior of booster pump 30. 
Such seal means comprises an annular wear resistant seal seat member 74 
mounted in a recess in the adapter 70 with shaft 50 extending through the 
inner opening 71 therein. The outer rim of seat member 74 receives an 
O-ring seal 76 constructed and arranged to provide a seal between seat 
member 74 and adapter 70 and to hold seat member 74 frictionally in a 
stationary position in adapter 70. The mechanical seal means comprises a 
sealing element 80 mounted for rotation with shaft 50 to cooperate with 
seat member 74 to seal the portion of shaft 50 extending from chamber 72 
to the exterior of adapter 70 as is well known in the art. Means are 
provided biasing sealing element 80 into sealing contact with seat member 
74, such means comprising a spring 84, a spring holder 86 and a snap-ring 
retainer 88 for spring holder 86, such parts being constructed and 
arranged so that spring 84 is in compression between spring holder 86 and 
sealing element 80 to thereby urge the same toward seat member 74. Such 
seal means are well known in the art. 
Conduit means are provided for connecting chamber 72 to the suction of main 
pump 10. Such conduit means comprises a drilled hole 90 in adapter 70 
communicating with chamber 72 and a pipe conduit 92 connected between hole 
90 and chamber 14 of main pump 10. By reason of this flow connection the 
pressure in chamber 72 is maintained to be approximately the same as the 
pressure at the suction of main pump 10. 
Means are provided for controlling a leakage flow from inlet chamber 34 to 
chamber 72 so that the high pressure in inlet chamber 34 is dissipated 
down to the low pressure in chamber 72, i.e., approximately the main pump 
suction pressure. Such means comprises spring holder 86 which has its 
internal wall 96 cooperating with pump shaft 50 with a close fit to allow 
minimal leakage flow therebetween. Spring holder 86 is received in a 
recess 98 in adapter 70 and held against axial movement by retainer 
snap-ring 88. An O-ring seal 100 provides a seal between the outer rim of 
spring holder 86 and adapter 70 and serves to frictionally hold spring 
holder 86 in a non-rotating position. 
Since the pressure applied to chamber 72 is reduced to a very low pressure, 
namely, approximately the pressure at the suction of main pump 10, by 
reason of the above-described construction and arrangement of parts, the 
mechanical seal for chamber 72 is subjected to less wear and will have a 
longer life than would be the case if the seal had to withstand the high 
pressure in inlet chamber 34 of booster pump 30. 
A typical fire fighting application in which the pump assembly is used will 
now be described with reference to FIG. 1. When the first fire truck 
arrives at the scene of the fire a tank valve 110 in a tank line 112 is 
probably already open. Tank line 112 is connected between a booster tank 
114 (which contains a supply of water) and main pump inlet 116. After 
setting the truck's parking brakes, the main pump 10 is engaged. The 
booster line's discharge valve 44 is opened and the fireman pulls the 
required amount of booster hose off the "live" reel, the engine is speeded 
up and the fireman applies the low volume, high pressure stream (straight 
or fog) to the fire. 
Meanwhile, a main pump inlet 120 is being connected via a 21/2 inch or 
larger hose 122 to the nearest source of water--usually a hydrant--or a 
second pumper stationed at a hydrant (or pond). The changover from using 
the fire truck's booster tank 114 to the external line supplying the inlet 
120 to the main pump 10 is usually done instantaneously and automatically 
when the main pump's inlet valve 124 is opened and the higher inlet 
pressure closes the booster tank's check valve 118 connected in tank line 
112. 
Usually simultaneously, a 21/2 inch discharge line is connected and laid 
between the main pump 10 of the first fire truck and the fire. After 
completing these connections and hose lays, a 21/2 inch discharge valve 22 
of the main pump 10 is opened and a high volume stream, using the lower 
main pump discharge pressure, is applied to the fire without requiring any 
interruption in the operation of the booster line. 
The pump assembly in accordance with the invention can be operated to 
deliver water from a suitable supply through either or both of the 
discharge valves 22 and 44. In a typical operation of the pump assembly, 
pump shaft 50 is driven from the transmission of the fire truck to cause 
main pump 10 to draw water at a hydrant residual pressure, say 20 p.s.i., 
and to discharge water to discharge passage 20 at a pressure of about 175 
p.s.i. When a discharge valve 22 is open and discharge valve 44 is closed, 
the water is delivered at about 175 p.s.i. to a first high flow rate fire 
fighting application (i.e. a discharge fire hose) and water is circulated 
through booster pump 30 to discharge tube 42 and by-passed back to the 
main pump suction at chamber 14 by way of conduit 49. This circulating 
flow through booster pump 30 prevents overheating of booster pump 30. When 
the discharge valve 22 is closed and discharge valve 44 is open, water is 
delivered to the inlet of booster pump 30 through pipe conduit 48 and is 
discharged from booster pump 30 through discharge tube 42 and discharge 
valve 44 at a pressure of about 400 p.s.i. to a second low flow high 
pressure fire fighting application (i.e. a booster reel). When both 
discharge valve 22 and discharge valve 44 are open, water is delivered to 
the discharge fire hose and the booster reel at pressures of 175 p.s.i. 
and 400 p.s.i., respectively. 
In accordance with the mode of operation described above, the volute and 
the impellers 36 and 38 of booster pump 30 are hydraulically designed to 
pump water optimumly at low volume and high pressure. Also, impellers 36 
and 38 are substantially smaller in diameter than the impeller 16 of main 
pump 10. This is shown clearly in FIG. 2. 
It will be noted that during operation of the pump assembly as described 
above, conduit 92 serves to apply the pressure of approximately 20 p.s.i. 
in the suction chamber 14 to the seal chamber 72 adjacent the inlet to the 
booster pump 30.