FR2591673A1 - Encapsulation resulting from the pivoting of a diaphragm concurrent with the axis of two concentric spheres and of two cones situated on the same axis concurrent with the axis of the spheres - Google Patents

Abstract

Device consisting of a pivoting or non-pivoting diaphragm concurrent with the axis of the two spheres, one external sphere of radius R.1, the other an internal sphere of radius R.1. In the resulting space two cones C.1 and C.2 are situated on either side of the axis of the spheres, which cones are on the same axis. Radially to the genatrices of the cones there are embedded equidistant and radial blades, which are tangential to the spheres via their ridges. The inclined or non-inclined position of the diaphragm determines two identical top-to-toe cells which the blades can block off by rotating, if the design of the diaphragm allows it. The volume situated between two consecutive blades will pass, for the same cell, from a minimum value to a maximum value, and then vice versa. The principle applies if the diaphragm only determines one cell. This device may be used for transporting a fluid. The device according to the invention is particularly intended for hydraulic pumps and motors with a variable or non-variable flow rate, for rotary internal combustion engines with a continuous cycle, and for rotary compressors.

Description

industrial hydraulic pumps and motors belong
to three main types: external or internal gears,
vane, radial or axial pistons. Each of these types has
characteristics which are specific to it from the point of view of pressure, flow, efficiency and internal tightness. However, the flow domain
important under high pressures, so that of large
powers, cannot be approached by these categories under penalty of
prohibitive dimensions and weight.

The present invention implements a design which solves
this issue.

Or two concentric spheres, one of which has radius R1
and the second interior of radius R2, and two cones C1 and C2 with bases
spherical with radii R1 and R2. These cones are located on a meme axis XX1 competing with the axis of the spheres. Are linked to these cones equidistant and radial pallets to the axis XX1; the pallets are
tangents by their profile outside the sphere of radius R1, and
by their profile inside the sphere of radius R2. A diaphragm
circular, rotating around the axis XX1, and pivoting on an axis YY1,
the axis YY1 being perpendicular to the axis XX1 and passing through the axis
spheres, delimits according to its inclination two identical cells
head-to-tail between spheres, c8nes and diaphragm.

If the inclination is fixed, the two cells are fixed if the in
clinching is variable, the two alveoli are variable.

A shutter system allows the pallets to pass through the
diaphragm.

If we communicate a rotational movement to the cone-pa assembly
lettes, the volume between two consecutive palettes will change
during rotation, from a minimum value to a maximum value,
then from this maximum value to the minimum value; this on a meme
alveolus, provided that the diaphragm is inclined on its
axis. The same phenomenon is carried out on the other cell, but offset by 180. If we make this variation in volume act on a fluid,
it can be sucked in during the growth of the alveoli, and pushed back
during the decrease of the alveoli.

 Important note: the pivoting movement of the diaphragm does not make any geometric modification to the capsulism.

This principle is valid if the diaphragm does not determine
a variable or fixed cell.

There will be described below, by way of examples, nonlimiting examples,
two mechanical embodiments of the invention.

The first concerns a double hydraulic pump with variable flow,
this pump can operate as a variable double displacement motor.

The second embodiment deals with a variable displacement motor with
single cell.

Extrapolating these two examples, we can design pump-motors
fixed displacement, single or double.

FIRST EXAMPLE: Dual motor pump with variable displacement, controlled
of variation by screw.

-Figure 1 represents the longitudinal section along the tree
motor or receiver.

FIG. 2 represents the cross section along the axis of
diaphragm pivoting.

FIG. 3 represents a section perpendicular to the axis of the
cones and located on one side of the diaphragm.

-Figure 4 represents a longitudinal section of the pallets
showing the practical realization of the seal between the pallet,
diaphragm and cone.

-Figure 5 represents the connection between the two chambers
discharge opposite to 1800 and the fluid outlet under
pressure in the pivot axis of the diaphragm.

 Or two half-casings 1 and 13 assembled together. In the assembly plane P, on the same axis XX1 are located a cone C1, marker 2 and a cone C2, marker 3. These cones have their large spherical convex base of rayan R1 and their small concave spherical bottom @ of radius R2. The two cones are made integral by the coupling bar 9. The outer sphere is materialized by the soft d @@ i- shells 4 and 5 assembled by the tie rods 17. The sphere i @ téri @ ure is materialized by the part 7 which serves as a diaphragm at the same time. These spheres are concentric one to the other and their common center is located on the axis XX of the cones C1 and C2. the pallets 10 (see fig. 1,2 and 3) are embedded on the generator of the cones, are radial to the axis XXI, and are on an odd number.

the bushels 8 allow the passage of the pallets through the diaphragm with sealing and the separation of the chambers V1 and V2
The rotating crowns 6 and 6bis control the inclination of the
diaphragm along the pivot axis YY1 which is perpendicular to the axis XXI.

 The linkage 14, 15 and 16 carries out the micrometric control of the inclination of the diaphragm from outside 11.

 The pivot axis of the diaphragm is materialized by the parts 11 and 12, these parts are fixed on the half-shells 4 and 5.

 The part 11 serves as a start of pressurized fluid in the case of a pump, as a fluid inlet in the case of an engine.

 The pipes 18 and 19 join the cells V1 and V2.

 In Figure S, we see the pallets osculate a cell. When passing at the top left point, the oil is sucked into the sump through the openings during the rotational movement of the pallet.

 If the diaphragm is inclined on its axis, the volume located between two consecutive pal @ ttes will vary during the whole lap, going from a minimum variation at the start, then a maximum variation and finally a zero variation at the end of the + lap.

 The pallet then passes to the delivery phase, and the oil is drained during this phase during the entire volume change.

 The discharge oil from cell V2 is combined with that from cell V1 by lines I8 and 19, these two d bits are discharged towards use by axis 11.

From this example we draw the following conclusions:
- the tilt movement of the diaphragm on its axis does not bring
no modification to the geometry of the organs.

 - The possible variation in volume is very large.

- The spherical system is the one that allows the largest
volumes in the smallest dimensions.

- The seal is excellent, the ranges being important and
constants.

- The motor or resistance torque is appreciably perp @ ndiculair @
to the axis of rotation, therefore of maximum effect.

- Hydraulic balancing is achieved by perfect opposition
alveoli.

- The central tie cancels the hydraulic reactions, it authorizes
direct coupling of accessory organs.

- The odd number of pallets reduces the pulsation to a very
low value.

 - The flooded solution brings the absence of maintenance and longevity.

 Note: the displacement control can be automated and controlled according to an order; to understand the principle, a simple screw-nut system has been figured.

 SECOND EXAMPLE: Single variable displacement motor. See fig. C, 7, and 8.

 The operating principle is the same as that of the double pump, but the mechanical construction differs significantly.

 In a casing 50 a cone is journalled, the large base of which is spherical convex of radius Ri and the small spherical base concave of radius R2.

 The outer sphere is produced by the part 52, the inner sphere by the part 53. These two spheres are concentric and their axis is located on the axis of the rotating cone.

 The diaphragm is constituted by the part 58 linked to the part 59; the assembly pivots around an axis 55, contributing to the axis of the spheres and to the axis of the cone. This axis 55 further comprises the oil supply ducts under pressidn and the oil return pipes. It has at its rear part a cylindrical reaction pad which allows it to pivot.

 The pivot axis is on the axis of the spheres. The pivoting of the axis 55 generates the variation in volume of the cell formed between the spheres, the rotating cone and the diaphragm.

The pallets 60 are linked to the diaphragm, pivoting on the latter, and sliding during the rotational movement in slots made in the cae C1
The rotary stops 61 and 62 absorb the hydraulic reactions of the engine.

 A simple control by circular rack and worm gives a solution for the external co: rarande of the variation of speed of the motor. Any other system can be envisaged to control the speed of the motor to any order.

Claims (4)

1- Device allowing to generate a simple capsulism or  double, variable or non-variable, allowing a large ratio  variation in volume of the capsulism (s) during a  continuous rotational movement, without geometrical deformation  - size of the surfaces constituting the capsulism during this  variation in volume.  spheres.  are located on a meme XX1 axis contributing to the axis of  C1 and C2 with spherical bases of radii R1 and R2. These cones  , and the second, interior of radius R2, and two cones  concentric spheres, one of which has a radius R1  This device consists of the space between two  -orient to the sphere of radius R2.  outside the sphere of radius R1, and by their internal profile  to axis XX1, the pallets are tangent by their profile  Equidistant and radial pallets are linked to these canes  cones and diaphragm.  -sound, two identical lavaoles and spade between spheres,  passing through the axis of the spheres, delimits according to its inclination  an axis YrI, the axis YT1 being perpendicular to the axis XI1 and  A diaphragm rotating around the XX1 axis and pivoting on  the inclination is variable, the two cells are variable.  If the inclination is fixed, the two cells are fixed; if  through the diaphragm.  A rotating shutter system allows the passage of pallets  the diaphragm is tilted on its axis.  minimum value; this on a same cell and on the condition  to a maximum value and then from this maximum value to the  -tives will pass during rotation, minimum value  cones-pallets, the volume between two pallets consecu  If we communicate a rotational movement to the whole  shifted by I800.  The same phenomenon is carried out on the second cell, but  driven back by the decrease in alveoli.  it can be sucked up when growing. alveoli, and  If we make this variation in volume act on a fluid,  or combustible or non-combustible gas mixtures.  The device being able to convey liquid, gaseous fluids, 2- Device according to claim 1 could constitute the  principle of realization of pumps or hydraulic m @ eurs  with variable displacement in a large variation ratio;  or with non variable displacement. 3- Device according to claim 1 which can constitute the  principle of production of rotary explosion engines,  two-stroke or four-stroke, fixed displacement, large  expansion, reduced consumption and uniform engine torque.  total displacement.  is multiplied by the number of pallets to provide the  The unit displacement made between two IO reference pallets  two-cell capsulism.  for the space between two consecutive pallets for  Cycle 8 establishes on a single turn of rotational movement  alveolus V1, i.e. on a half-turn.  minimum of cell VI at the maximum volume point of  1st you s: Aspiration of the gas mixture from the volume point  located between two pallets at 1,800 of the previously mentioned pallets.  gases compressed by a pipe on cell V2 in space  the second half turn. At the minimum volume point, transfer of  volume @ maximum of V1 at the minimum volume point of V1 on  2nd step: On the same cell VI, gas compression of the point  taking place during the duration of the U-turn.  a continuous or discontinuous ignition system. Gas relaxation  3rd temple: Explosion of the gases from this V2 cell when passing over  remaining from cell V2.  4th step: Free exhaust during the entire U-turn  of these.  gas pressure would allow almost total relaxation  -list dedicated exclusively to the exploitation of the rest of  It should be noted that the addition in series of a second capsu 4- Device according to claim 1 which can constitute the  principle of realization of high speed rotary compressors  air or gas.  double, this in the case of a double flow compressor.  conveyed in the hydraulic pump embodiment  The gas cycle being the same as that followed by the fluid  single flow and double pressure.  If the cells are coupled in series, the compressor is at