Pumping device

A pumping mechanism comprising a flat base having a central vertical post and a pair of reciprocal pumping elements mounted on the flat base and situated on either side of the central post. Each of the pumping elements comprises an upper moveable assembly and a lower fixed assembly which slidably accepts the lower portion of the upper movable assembly. A driven member pivotally mounted at the midpoint of its length on the central vertical post has each end pivotably connected to each of the reciprocating pumping elements. The driven member serves to raise and lower the pumping elements in a smooth and steady fashion. A pair of collapsible piston assemblies are located within the upper movable assemblies of the reciprocal pumping elements and are collapsed and formed at the top and bottom of each stroke of the pumping elements.

FIELD OF THE INVENTION 
This invention relates to a pumping mechanism. 
This invention is a gravity assisted reciprocating pumping device. 
SUMMARY OF THE INVENTION 
The present invention is a pumping mechanism comprising: 
a flat base having a central vertical post; 
a pair of reciprocal pumping elements mounted on said flat base and 
situated on either side of said central post, each of said pumping 
elements comprising an upper movable assembly and a lower fixed assembly 
which slidably accepts the lower portion of said upper movable assembly; 
actuating means comprising a driven member pivotally mounted at the 
midpoint of its length on said central vertical post with each and 
pivotally connected to each of the reciprocating pumping elements, said 
driven member serving to raise and lower the pumping elements in a smooth 
and steady fashion; 
a pair of collapsible piston assemblies located within the upper movable 
assemblies of the reciprocal pumping elements; 
means for collapsing and forming said collapsible piston assemblies at the 
top and bottom of each stroke of the pumping elements.

DESCRIPTION OF THE PREFERRED EMBODIMENTS 
Referring to FIG. 1, there is shown a first embodiment of the present 
invention. Pumping mechanism 2 rests on a flat base 4. A central vertical 
post 5 is affixed to the center of the base and supports at its upper end 
a stationary horizontal member 6 and a driving member 8. Stationary 
horizontal member 6 is firmly attached to vertical post 5 so that it 
cannot rotate. Driving member 8 is pivotably mounted at its longitudinal 
midpoint to a sturdy pin 11 received in the top of central vertical post 
5. As can be seen from the drawings, there are two pumping elements 7 on 
either side of the central vertical post 5. As each pumping element and 
its associated working parts are identical, the whole pumping mechanism 
being symmetrical about the vertical post, the construction of only one 
side of the device will be discussed, it being understood that the same 
applies to the opposite side of the pumping mechanism. 
A pumping element 7 consists of two assemblies: An upper movable assembly 9 
and a lower fixed assembly 22 firmly attached to base 24. The upper 
movable assembly 9 is further divided into an upper container 16 with 
rectangular cross-section which houses a collapsible piston assembly 28 
and a lower hollow cylinder 19 attached to the lower end of the upper 
container 16. Upper container 16 has an upper surface 14 in which is 
formed an inlet opening 27, which communicates with a fluid source by way 
of an inlet hose. A short link 12 is pivotably attached to the top 14 of 
upper container 16, the link's opposite end being pivotably attached to 
one end of driving member 8. 
An internal lip 17 and an external lip 18 are formed around the perimeter 
of the lower edge of upper container 16. Attached to the external lip 18 
is adapter member 20 which forms a transitional aperture 21 between 
rectangular upper container 16 and circular lower cylinder 19. Hollow 
cylinder 19 is secured to the lower edge of adapter member 20 and 
communicates with upper container 16 through large aperture 21. 
The hollow cylinder 19 of movable assembly 9 is slidably received in lower 
fixed assembly 22 which consists of a second hollow cylinder firmly 
attached to base 4 with a slightly larger diameter than hollow cylinder 
19. Cylinder 19 has around its outer circumference a plurality of sealing 
members 24 that maintain a fluid tight seal between cylinder 19 and 
cylinder 22. A fluid discharge pipe 26 transports fluid from the base of 
cylinder 22 through a conventional one way valve 29 to a desired location. 
A collapsible piston assembly 28 is housed within upper container 16 and 
comprises a plurality of thin, flat closure plates 30 with upper surface 
tabs 31 as best shown in FIGS. 2 and 3. Tabs 31 are pivotably attached to 
link arms 42 and link arms 42 are in turn pivotably secured to central 
mounting plate 32 of guide frame 48. All closure plates have identical 
parallelogram cross-sections and the plates are arranged such that 
adjacent edges overlap - see FIGS. 2 and 7. 
As shown in FIGS. 2 and 7, guide frame 48 fits slidably within upper 
container 16. A plurality of small diameter rods 50 are mounted between 
the walls of guide frame 48 perpendicular to central mounting plate 32 and 
above closure plate 30. Rods 50 serve to restrict the pivotal movement of 
plates 30 as will be discussed below. 
The operation of the pumping device of the present invention relies on 
piston assembly 28 being formed and collapsed by appropriate means. In the 
embodiment of FIG. 1, the piston collapsing and forming means comprises 
the linkage system interconnecting piston assembly 28 and stationary 
horizontal member 6. This linkage system includes upwardly extending link 
34 which is pivotably attached to central mounting plate 32 of piston 
assembly 28. Link 34, in turn, is pivotably attached to a second shorter 
link 36. Link 36 is pivotably secured to the top 14 of upper container 16 
by tab 54. Projection 55 extends perpendicularly from link 36 and is 
slidably engaged in slot 56 of link member 57. Link member 57 extends 
through the top 14 of upper container 16 and is pivotably connected to one 
end of stationary member 6. 
FIGS. 4 and 4a are more detailed views of the linkage system found inside 
upper container 16. Heavy duty helical spring 60 is wound around pin 61 
which forms the pivoting joint between tab 54 and link 36. Ends 62 and 63 
of spring 60 are attached respectively to tab 54 and link 36 and spring 60 
is installed about pin 61 in a known manner so as to cause link 36 to 
rotate upwardly in a counterclockwise direction about the axis of pin 61 
as shown in FIG. 4 when the collapsible piston assembly is not in a closed 
position as will be more fully described below. 
A locking system comprising pawl 100 and ratchet 105 is located towards the 
lower end of link 36. Ratchet 105 with single recess 107 is mounted on pin 
67 which forms the pivoting joint between link 36 and link 34. Pawl 100 is 
pivotably mounted to arm 36 by pin 101. Biasing spring 102 serves to force 
locking arm 108 against the outer circumference of ratchet 105. Pawl arm 
109 ends in angled flange 110 which can engage tab 115 attached to the 
lower end of slotted link 57, the surface 116 of the tab beginning on a 
line tangential to the lower end of slot 56 and perpendicular to the 
longitudinal axis of slotted link 57. 
In the embodiment of FIG. 1 the entire pumping mechanism is operated using 
a conventional hydraulic system as shown in FIG. 5. Two sets of driving 
links are pivotably attached on the longitudinal axis of driving member 8 
to opposite sides of central post 5. Each system of links comprises a 
long, vertically disposed link 72 pivotably connected at its upper end to 
driving member 8 and pivotably connected at its lower end to one end of a 
shorter, horizontally disposed link 74. Link 74 is pivotably mounted at 
point 71 along its length to support 76 and pivotably secured to piston 78 
of a conventional hydraulic cylinder 80 at its end opposite that attached 
to link 72. As is shown schematically in FIG. 4, the hydraulic motor 82 
communicates with cylinder 80 via hydraulic lines 84. An oil reservoir 86 
is provided. 
The pumping mechanism of the first embodiment operates as follows: 
Motor 82 circulates hydraulic fluid through lines 84, into reservoir 86 and 
through a further set of hydraulic lines that are connected to cylinders 
80 and 81. As shown in FIGS. 1 and 4, the inflow of fluid into the right 
hand cylinder 81 causes the piston 78 to be forced upwardly. This causes 
link 74 to pivot about support 76 and pull link 72 downwardly. Since link 
72 is attached to drive bar 8, the bar 8 is pivoted about pin 11 and 
pulled downwardly on the right side. The opposite end of the drive bar 8, 
the end on the left of FIG. 1, is correspondingly raised. When piston 78 
reaches the upper limit of its travel, hydraulic fluid is switched to the 
opposite hydraulic cylinder 80, and through an identical process as 
described above, the upward movement of the piston in hydraulic cylinder 
80 causes the left hand side of drive bar 8, as shown in FIG. 1, to be 
lowered. Thus, this movement of hydraulic fluid between cylinders 80 and 
81 by the action of hydraulic motor 82 causes the drive bar 8 to be 
pivoted about the pivot pin 111. 
The pivoting motion of drive bar 8 about pivot point 11 serves to drive the 
upper movable assemblies 9 of pumping elements 7 up and down as short link 
12 transmits the reciprocating motion of the driving member 8 to each 
pumping element. 
In turn, the reciprocating motion of the upper movable assembly 9 serves to 
power the operation of the rest of the pumping mechanism. Fluid, flowing 
under gravity, continually enters both pumping elements 7 through openings 
27 in the tops 14 of upper containers 16. As an upper movable assembly 9 
moves upwardly during a stroke, the upper end of slot 56 formed in slotted 
link 57 applies a force to tab 55 extending perpendicularly from link 36. 
This applied force causes link 36 to rotate downwardly about pin 61 
connecting tab 54 and link 36. Accordingly, the downward motion of link 36 
causes piston assembly 28 to move downwardly in upper container 16. The 
downward motion of link 36 also tensions helical spring 60. When an upper 
movable assembly 9 reaches the top of its stroke, slotted link 57, acting 
on tab 55, has rotated link 36 sufficiently to allow locking arm 108 of 
pawl 100 to engage recess 107 in ratchet 105; thereby locking arm 34 in 
position to hold collapsible assembly 28 closed against flange 17 of upper 
container 16, as shown in FIG. 4. Collapsible piston assembly 28 now 
appears as in FIG. 3. Closure plates 30 are sealed against internal flange 
17 of upper container 16 and this sealing of the closure plates 30 
separates the pumping elements 7 into two volumes, an upper volume 
consisting of upper container 16 and a lower sealed volume comprising 
hollow cylinder 19 slidably received and sealed with rings 24 inside 
cylinder 22. 
Upper movably assembly 9 now begins moving downwardly in its normal pumping 
cycle. As upper container 16 is forced downwardly by driving arm 8 the 
lower sealed volume decreases as hollow cylinder 19 slides into cylinder 
22. As a result, water in the lower sealed volume is displaced, through 
the one-way valve 29 in fixed cylinder 22, into discharge pipe 26 and to 
the desired location. As upper movable assembly 9 moves downwardly, tab 55 
slides freely downwardly in slot 56 of slotted link 57, and piston 
assembly 28 remains in its closed sealed position. In addition, fluid 
continues to flow into upper container 16 which is now sealed at its lower 
edge by closure plates 30. This increasing mass of fluid provides 
additional weight which assists driving member 8 in moving upper movable 
assembly 9 downwardly. The additional weight of incoming fluid also 
assists in holding closure plates downwardly against internal flange 17 
against the fluid pressure developed in the lower sealed volume. Closure 
plates 30 are also held in place and prevented from pivoting about arm 42 
by rods 50 mounted between the walls of guide frame 48, as shown in FIG. 
2. 
When upper movable assembly 9 reaches the bottom of its stroke, the lower 
end of slot 56 applies an upward force to tab 55 and, at the same time, 
releasing tab 115 of slotted link 57 engages angled flange 110 of pawl 100 
pivoting the pawl 100 about point 101 and releasing locking arm 108 from 
recess 107. With arm 34 no longer locked in position, the force applied by 
the lower end of slot 56 on tab 55 begins to rotate link 36 upwardly, 
raising piston assembly 28. The upward movement of piston assembly 28 
causes closure plates 30 to open slightly due to the mass of fluid above 
acting on the plate when the plates are no longer supported below by 
internal lip 17. With closure plates 30 now slightly opened to allow fluid 
to pass through into hollow cylinder 19 and fixed cylinder 22, tensioned 
helical spring 60 provides the necessary force to cause link 36 to swing 
upwardly, sliding piston assembly 28 upwardly in upper container 16 into 
its fully open position shown in FIG. 2. Tab 55 slides along slot 56 until 
the upper end of the slot is reached. Slotted link 57 pivots about its 
attachment point to stationary bar 6 to allow tab 55 to slide smoothly 
along slot 56. Upper movable assembly 9 continues its upward travel with 
open piston assembly 28 offering much reduced resistance to fluid flow. As 
upper movable assembly 9 travels upwardly, the upper end of slot 56 
applies a force to tab 55 which slowly closes piston assembly 28 in the 
manner previously described. When the upper movable assembly 9 reaches the 
top of its stroke, link 34 is locked into position, sealing piston 
assembly 28 against internal lip 17. The cycle as previously described is 
then repeated. 
It will be appreciated from FIG. 1 that when one pumping element 7 is 
moving downwardly and pumping fluid the other is moving upwardly. Thus, a 
continuous flow of fluid is pumped through outlet pipe 26 by alternating 
pump strokes of the two pumping elements. 
FIG. 6 shows a second embodiment of the present invention which uses a 
different means for forming and collapsing the piston assembly 28. As 
well, the embodiment of FIG. 6 uses a different drive system comprising 
rotating cogs 150 and link arms 152 driven by central drive shaft 149 in 
order to reciprocate driving member 8. This drive system is an alternative 
to the previously described hydraulic system and as such the two drive 
systems are interchangeable. 
In FIG. 6, parts of the pumping device corresponding to those of the first 
embodiment are similarly numbered. The actual pumping action of the pump 
device is as previously described with a gravity fed supply of water 
entering through opening 27 and being pumped through one way outlet valve 
29 and discharge pipe 26. Collapsing and forming the piston assemblies 28 
is done differently, however. The stationary horizontal member 6 of FIG. 1 
is replaced by pivoting bar 153 joined to central vertical post 5 at joint 
11. Pivoting bar 153 is connected at each end through links 154 with 
connecting links 36 within the upper container 16 of a pumping element 7. 
The movement of pivoting bar 153 is coordinated and controlled by pivoting 
assembly 156 mounted to post 5 at pivot 157. Pivoting assembly 56 is 
mounted to post 5 such that the end portions of the assembly extend to 
either side of an imaginary vertical plane through post 5. Attached to and 
extending outwardly from opposite end portions of pivoting assembly 156 
are hook members 158 and 159 and collapsible link members 160 and 161. 
Hook members 158 and 159 extend upwardly and outwardly and are slidably 
support in eyes 162 on pivoting bar 153. The upper end of hook members 158 
and 159 are formed into hooks adapted to engage the upper surface of 
pivoting bar 153 as required. Collapsible link members 160 and 161 are 
formed from pivotally connected links and extend from opposite and 
portions of pivoting assembly 156 to opposite sides of driving bar 8 such 
that the link members cross each other and intersect the vertical plane 
through post 5 as shown in FIG. 6. Spring 163 is attached to one end 
portion of pivoting assembly 156. Spring 163 extends downwardly to mount 
164 on post 5 and serves to tilt the pivoting assembly to one side of post 
5. 
As in the embodiment of FIG. 1, the present pumping device is moved by the 
external power source which in this case is the rotating cog drive. Link 
arms 152 reciprocate drive bar 8 to drive the upper movable piston 
assemblies 9. In FIG. 6, the upper movable piston assembly on the left is 
just beginning a downward pumping stroke as indicated by arrow 167 and the 
upper movable piston assembly on the right is just beginning an upward 
stroke as indicated by arrow 166. Pivoting assembly 156 is tilted to the 
left due to the action of spring 163 and straightened collapsible link 
member 161. This tilting of the pivoting assembly 156 causes hook member 
159 to descend relative to pivoting bar 153 thereby engaging the upper 
surface of the bar and pivoting the bar to the left which causes the left 
hand side piston assembly 28 to be formed and sealed ready for the 
downstroke. At the same time, hook arm 158 and the right end of bar 153 
move upwardly causing the right hand side piston assembly 28 to collapse 
to ease the upstroke motion. 
Collapsible link members 160 and 161 provide the means to tilt pivoting 
assembly 156 so that hook members 158 and 159 engage pivoting bar 153 at 
appropriate times to form and collapse piston assemblies 28. Collapsing 
and forming the piston assemblies only needs to occur at the top and 
bottom of each stroke. As the right hand upper movable piston assembly 
moves upwardly collapsible link member 160 will tend to straighten while 
collapsible link member 161 will tend to collapse. Therefore, when the 
right hand pumping element reaches its uppermost position and the left 
hand pumping element reaches its lowermost position, collapsible link 
member 160 will be straight while link member 161 will be collapsed 
causing pivoting assembly 156 to pivot to the right thereby forming the 
right hand piston assembly and collapsing the left hand piston assembly in 
preparation for continued motion of the pumping device. Such a collapsing 
and forming action occurs for each cycle of the pump.