OA19581A - Pressurized pressure pump. - Google Patents

Abstract

The pressurized pressure pump is made up of three (3) parts (G, H, I) each having played a role distinct from each other in its operation. By its singularity of having a pumping axis different from the water rising pipe, thanks to the double valve and the pressure chamber that it has in its construction system. There is the possibility of double pumping with the sets of cylinder-piston and two associated tubes (I, H). Then the pumping movement is carried out in a rotary manner, such are the characteristics of this pump. It also has the particularity of pumping water, from the borehole, or the well so that part of the water is poured into the castle and the other part of the water is poured into the container placed at the same the ground, or depending on the setting of the sharing valve, part of the pumped water is poured into the castle tank and the other part into the bucket placed on the ground, or even the double is poured into the container placed in down, the other half in the castle and vice versa. The device of figure (7), depending on the setting of its construction system, could be deported and installed from a borehole, from a well, from one river to another as being a motor pump. It is therefore portable according to certain needs. Figure (1), of the board (I) is made up of all the constructive elements of the machine, side view.

Description

The present invention relates to a pressurized pressurized pump.

In this time of very advanced technical progress where pressing and submerged pumps are proving their worth in pumping groundwater, we are modestly proposing this new version, which can be the subject of a junction between these two previous ones by its originality.

The fulling pumps are manufactured, in fact of cylinder-piston couple. The cylinder has in its lower part, a valve, which can close and open the orifice of the latter. As for the piston, it in turn has a valve with an orifice at its center, which orifice is welded to a pipe, serving as the pumping axis. This compression pump works in a unilateral way, that is to say by the back and forth movement of the pumping axis. If the piston-ring couple is pulled up, the water enters through the orifice at the bottom of the cylinder, entering the valve rises, and the orifice opens. But on the other hand, if you push the piston down, the opposite effect is repeated; the valve opens and water enters the axial pipe and rises outwards; meanwhile, the valve at the bottom of the cylinder closes the orifice. So by the reciprocating movement of the piston, the valves open and close alternately, therefore, water rises through the pipe of the pumping shaft in a continual manner. This pump cannot pump water from the borehole and pour it into the castle, since the design of the latter is made to pour the pumped water only into the container placed on the ground.

The submersible pump, on the other hand, has an electric motor, placed inside a cylinder having at its two ends valves each with an orifice. Under the effect of electric current, the motor turns, raises the water, thanks to the blades attached to the rotor, under pressure, the water penetrates through the orifices and rises in the pipe towards the outside of the pump, these are the functional characteristics of these two types of pumps that are found on the markets. The submersible pump, for its part, operates under the effect of electric current, as long as it is off the electricity grid, there is no possibility of supplying the castle, nor of obtaining water.

While both fulling and submerged pumps have performed well in pumping, they do not do so in small human domestic installations. For example, the pressurized pressure pump carves out the functional intersection between these two previous ones

described above. The pressurized pressure pump has the possibility of pumping water from a borehole, a river or a well so that part of the water is poured into the castle and the other part into a container placed directly on the tank. ground. It has a preset setting of a share tap. This pump has an advantage over the other two by virtue of its system having two valves interposed by an orifice carrying at its end by the cylinder-piston couple. This device allows it to have the water pipe separate from the pumping axis, hence the possibility of carrying the water also higher in the castle. Added to this is the pressure chamber, which in turn greatly increases the pressure on the water. It should also be noted that this arrangement of separating the water pipe from the pumping axis gives our pump the possibility of juxtaposing the pistons and carrying out a double pumping, then the pumping lift is done in a rotary manner. see fig. (2), fig. (3).

The pressurized pressure pump is made up of three parts (G, H, I), see layout of plate (II), figure (3):

Part (G) is made of a cylinder-piston pair (j) is connected to a pumping pin (a), and carried around it, two segments (f). The cylinder has in its lower part an orifice (c) for water intake and discharge.

Part (H) is a tube having an orifice at the bottom, equipped with a valve associated with a pipe extending in its upper part having an orifice at (e). Then containing a suspended pipe, one of the orifice opens in its lower part and the other orifice (k) opens to the outside of the tube (H).

Part (I) is a tube communicating with that of (H), having in its upper and lower part, a valve device (b), interposed with one another by an orifice (q), directly connecting ( 1) to (G). All of these three parts distinctly constitute figure (2,3), all mounted in a box, see plate (III), figure (4), page (11) whose point (m) serving the orifice water inlet, this constitutes the actual pressure pump.

Point (a) is an axis of reciprocating pumping movement, (d) is the outlet pipe for water from the pressure chamber to the outside of the pump and, (g) is at the end of the filter.

The elements (2, 3) of page (12), are parts manufactured in duplicate, have enclaves in which are placed the device of the element (6), consisting of: Bearings (n), a connecting rod (o ), a crankshaft (x). Part (1) is

a sleeve with a wrist at its end. The whole of this assembly is fixed by a base of the element (5) also manufactured in duplicate and, the whole forms a single block figure (7), side view. The latter can be deported wherever needed, provided that the piston pin (a) of the pump is connected to that of the connecting rod (o). This is the bulk of the mechanical part of our machine.

Figure (5) is a part, serving as a foot to support the assembly of figure (7), see the board (IV), it has in its center an orifice (y), through which passes the fixing axis of the pump inside which the second piston pin is located, see assembly plate (V), figure (8), point (y).

The part of the board (III), figure (6), page (11) is a tank, it has in its lower part a valve (j) playing the role of non-return of water and, is extended by a pipe Up to half the height of the tank, the point (!) Is used to regulate the pressure in the tank.

Items (i) and (h) on page (H) serve respectively, the bucket for collecting water from tap RI, and (h) is the container with water serving as a water well , see figure (l) of plate (I).

Element (w) of the board (V), figure (8), page (13) is a support for fixing the tank to its mast.

Figure (1) of the board (I) is the panoramic profile view of the machine.

R2 of the board (V) figure (8), page (13) is a tap that can receive water from the water tower.

(u) of the board (V) is the water pipe from the pump to the tank and / or RI valve, via the set point (v).

(c) is the water pipe from the reservoir to the R2 tap, see the board (v), page (13).

The point (t) is a connecting element between the axis coming from connecting rod (o) on the one hand and the axis (a) coming from cylinder-piston (j) on the other hand. This point (t) of the board (v), figure (8), page (13) is also used to adjust the piston stroke in the cylinder and also makes it possible to shorten or extend the rod of the axis (a), by following the drilling depth.

(s) in Figure (8) is the wrist, allowing the water pump to attach to the machine frame to turn the crank. (1) is the adjustment valve

pressure. If it is open, the water in the castle is under the normal condition of temperature and pressure, but if it is closed, the water in the tank is under high pressure and the water is out. valve R2 for this purpose, can squirt with great pressure.

The operation of the pump is not as complicated as, it was thought, we will describe the mounting assembly of the board (V), figure (8), page (13), front view, top to the bottom, as well as that of the water rise circuit board (II), figure (2,3), page (10) which is carried out, from the pump immersed in the borehole or well, to the reservoir of castle water. The rotational movement of the crank (1), page (12), fixed to the crankshaft axis (x), having at its two ends of bearings (n), which is initially a rotational movement, will be transformed into a back and forth movement, along the connecting rod axis (o) perpendicular to the crankshaft axis from top to bottom. All of these elements constitute element (6), taken from a casing figure (7). Using a connecting rod (o), welded for this purpose, to the axis of rotation of the crankshaft, will be connected to an axis (a), connecting at its lower end, the cylinder-piston couple, the whole placed at inside a box figure (4), at the bottom of the latter, there is an orifice (m). Thus, according to this description, the machine starts mechanically.

Regarding the rising water circuit, the element (h) of the board (I), figure (1), page (9) serving as a borehole containing water, will accommodate the pressurized ram pump figure (4), page (11) which through its orifice (m), water will enter and take place in the housing, then it enters through the filter orifice (g) page (10), then enters through the first valve orifice (b) of tube (I). By the back and forth play of the piston pin (a), the two valves (b) of two tubes (I, H) open and close alternately, so that when the piston is pulled towards at the top, the water enters through the filter, pushes the first valve upwards and concentrates in the tube (I), in the meantime the upper valve closes tightly. When you push down, the opposite effect occurs, the lower valve closes, then the upper one opens, water spurts out through the orifice (e) of the pipe, s' flows to the bottom of the other tube chamber (H). This tube (H) retains in its upper part a space containing air (z), under pressure, with the arrival of water, the pressure increases, the water rises inside the second pipe (d) and arrives at the set point (v). This adjustment consists of raising the water, either in the tank through the non-return valve (j), placed at the tank inlet, or directly pouring it into the bucket (i) at

through the RI tap, or if the setting is well established, we receive at the same time, either the same quantity of water, both in the tank placed at the top and in the bucket placed on the ground, or one receives double, the other half and vice versa. This is where the advantage of the pressure pump becomes clear over the other two described above. This is to say that the "pressurized pressure pump" plays both the same role of a pressure pump and a submerged pump.

We can highlight three examples in which the way of industrial application is possible:

Take, for example, a slaughterhouse, where the workers pump abundant water to meet their slaughtering needs. If our pump model is installed, half of the water pumped at this time is mounted in the storage tank, and it will be used at the end of the slaughter, since the need for pressurized water is desirable for cleaning of feces, blood and equipment in general.

- Take the case of an isolated health district, users using this pump, half of the water is then reserved in the castle, and will be used by nursing staff.

- Another scenario is that of schools in rural areas, where students can use water from the pump. But part of the water reserved in the castle will be used by the dispensary installed within it, for the use of small surgeries, or used in the establishment's experimental laboratories.

The device of this pressurized compression pump can be used in many other advanced technologies.

Claims (12)

1. Pressurized pressure pump comprising a part G communicating with a part I through their orifices (c) and (q), another part H interposed between G and 1 communicates with part I via an orifice (b) carrying a valve located at its lower part, this orifice is extended by a pipe (z) and opens at (e), said part H also has a second pipe (d) which extends from its lower part and which opens at the outside by an orifice (k). 2. Pressurized pressure pump according to claim 1 where part G comprises a cylinder-piston pair (j), said pair is connected to a pumping pin (a) and the cylinder has an orifice (c) of intake and discharge in its lower part, said piston has around it two segments ensuring the seal between the cylinder and piston. 3. Pressurized pressure pump according to claim 2, wherein part H is a tube having an orifice (b) in its lower part carrying a valve, which valve is extended by a pipe (z) opening. in (e), said tube H has another tube (d), one of the two orifices of which originates in the lower part of the tube and the other orifice opens to the outside at (k), passing through the upper part of said tube, said tube is the actual pressure chamber for the pump. 4. Pressurized pressure pump according to claim 2, wherein part I is a tube having two orifices (b) each carrying a valve, one in its upper part and the other in its lower part. The orifice of the upper part making the line of communication between the tube I and H, extending by a pipe which opens in (e) in the pressure chamber, the second orifice opens to the outside in the lower part connected by a pipe coming from the filter (g). 5. Pressurized pressure pump, characterized in that the pumping axis is different from the water pipe. 6. Pressurized pressure pump characterized in that the pumping lift is carried out in a rotary manner. 7. Pressurized pressure pump characterized in that the rotary movement device, can be used in hydraulic dam installations, in the wind and solar system. 8. Pressurized pressurized pump characterized by its four feet and the device for raising and lowering the pump, allowing it to be installed anywhere as needed. 9. Pressurized pressure pump according to claim 5, gives it the possibility of transferring a liquid, a gas or any other fluid from one container to another. 10. Pressurized pressure pump according to claim 5, allows it to have double pumping by the juxtaposition of its system. 11. Pressurized pressure pump, according to claim 5, for pumping water from a borehole, a river or a well so that part of the water is poured into the castle and another part in. the container placed on the ground, according to a predefined setting of a sharing tap. ίο 12. Pressurized pressure pump, according to claim 3, converted to a castle connecting to the pump and having in its upper part an air control valve, the water contained in the castle is under pressure depending on whether the air valve is closed or open.