FR2711740A1 - Multiple-rotor gas intake system - Google Patents

Abstract

The invention relates to a device making it possible to draw in air or other gases and deliver them without energy losses due to stirring, compression or unprofitable depression. It consists of a central rotor having four cavities allowing accurate passage of the engaging tooth-type partitions of the two lateral rotors, the diameter of which is half that of the central rotor. The air is drawn in, locked between the two partitions then delivered. In the bottom of the cavities there are ducts corresponding to a fixed drain which allow the air trapped by the partition in the cavity during rotation to be evacuated. This device is advantageously intended to replace noisy turbines (fans) with limited depression in household and industrial vacuum cleaners.

Description

 The present invention relates to a device for sucking in air or other gases, simply discharging it at its outlet without compression.

 Currently, depending on the applications, the technology offers a wide range of devices ranging from vacuum pumps to compressors, including all categories of noisy turbines. Some are adapted to obtain a significant depression upstream with the design and production constraints that this supposes, conversely, seek to obtain maximum compression downstream.

 The device presented is intended to be simple in terms of design and operation and therefore energy efficient. This is why, it seeks to minimize the energy losses by compression or vacuum without interest or by simple mixing of noisy and useless air.

 The device which is the subject of the present invention blocks a certain volume of air or gas whatever its pressure or its depression and the transfer without leakage to its downstream discharge. The air flow transferred is directly proportional to the dimensions of the device and its speed of rotation. This suction system is composed in the version presented, of a central cylindrical rotor (1) and two lateral rotors (2) of half diameter therefore rotating twice as fast. These three rotors are enclosed in a casing (3) opening in the plane of the axes. This set has practically 3 planes of symmetry.

 Figure 1 shows a section of the entire device to see the three rotors townant against each other without friction or sliding due to the ratio of diameters. It also makes it possible to see the particular profiles of the partitions (5) of the side rotors (2) of the gear teeth type and of the cavities (4) of the central rotor (1).

 Figure 2 shows a view of the device in section along the plane of the axes of the rotors with the central rotor (1) in place. Figure 3 shows the same thing but with the side rotors (2) in place.

Figures 4 and 5 show perspective views of lateral and central rotor
With reference to these drawings, the device presented in FIG. 1 therefore comprises 3 rotors:
The central cylindrical rotor (1) has four cavities (4) machined sw all the longw of it. Their particular profile corresponds exactly to the passage of the point of the partitions (5) (gear tooth type) of the lateral rotors (2). At the bottom of these cavities (4) are a series of channels (9) machined in the direction of the axis on the 'front part according to the rotation, of these cavities. These channels (9) allow air to trap in these cavities
(4) during penetration of the side rotor guts, to be evacuated effortlessly by the fixed drain (10) machined like a groove on the fixed central axis (8) integral with the casing
(3); The evacuation of this fixed drain (10) being on the side where it is fixed to the casing (3).

 It should be noted that this fixed axis (8) does not cross the entire length of the central rotor since, on the other side, this rotor has its axis of rotation (13) driven by the motor.

We can see in this same drawing that the bottom channels (9) of the 4 cavities pass in front of the fixed central grooves (10) serving as a drain when the partition (5) enters the cavity. Due to the rotation, this communication closes from the moment when the partition has penetrated as much as possible into this cavity. Thus, when it continues its rotation, it provides an empty volume of air to the depression of the opening (6) of the casing (3) (suction side). The air blocked between the two partitions is therefore fully discharged without compression by the discharge outlets (7) or by the drain (10) on the side opposite the drive shaft (13) without possible return.

This same figure shows the synchronization gear discs (12) of the three rotors imposing a precise rotation twice as fast for the lateral rotors (2).

This precise synchronization avoids the risks of catching partitions at the center of the cavities of the central rotor. In addition, a belt can easily connect the two lateral rotors which have the same direction of rotation.

The lateral rotors (2) are obviously the same length as the central rotor (1) but they have at their ends a puddle (11) of diameter slightly greater than the diameter of the 2 partitions (5). These flanges are intended to avoid the problems of lateral sealing of the rotating partitions, the problem being simpler to solve on the periphery of these flanges.

The profile of these partitions (5) corresponds exactly to the passage of the edges of the cavities (4).

This profile thus offers 3 sealing points 1) the front edge (according to the rotation) of the cavity against the front part of the partition which penetrates it, 2) the point of the partition against the cavity, 3) the rear edge of the cavity on the rear part of the partition.

 The partitions (5) may have a slightly enlarged head of a few degrees, which gives it a second point, which, in the same way, makes it possible to offer an additional sealing point.

In this case it is the trajectory of the front point of the partition which traces the profile of the front face of the cavity and the rear point which traces the profile of the rear face of the cavity.

The front and rear profiles are obviously rigorously symmetrical.

The casing (3) is composed of two symmetrical blocks along the plane of the axes of the rotors. It serves as a watertight cradle for these three rotors. Each block has an opening for suction (6) and an opening for delivery (7). It is on these openings that the suction (14) and discharge (10) conduits are fixed, adapted to the specific application of the device.

 The device according to the invention is particularly intended to equip household and industrial vacuum cleaners by advantageously replacing the noisy turbines and vacuum limits which are currently used for these types of devices.

Claims (9)

 1) Gas suction device characterized in that it consists of a central rotor (1) comprising cavities (4) and lateral rotors (2) comprising partitions, gear tooth type (5) , The assembly being enclosed in a casing (3).  2) Device according to claim 1 characterized in that the profile of the cavities (4) is drawn by the path of the point or points of the partitions (5) of the side rotors (2) and that the profile of these partitions is itself even drawn by the path of the front and rear edges of the cavities (4) of the central rotor (1).  3) Device according to claim 2 characterized in that on the half front face, according to the rotation, from the bottom of these cavities, are machined channels (9) in the direction of the center of the axis of this central rotor (1 ).  4) Device according to claim 1, characterized in that the central rotor (1) has at its center a fixed axis (8) over about three quarters of its length, which is integral with the housing (3).  5) Device according to claim 4, characterized in that this fixed axis (8) has over its entire length two grooves (10) diametrically opposite serving as a drain to evacuate the air trapped by the partitions (5) of the side rotors during of their penetration into the cavities (4) of the central rotor.  6) Device according to claim 5 and 4, characterized in that these rainwes (10) are in correspondence, during the penetration phase of these partitions, with the channels (9) machined in the bottom of the cavities (4). Then by simple phase shift due to the rotation of the rotors, the passage closes in the phase of maximum penetration of the partition (5), thus offering an empty volume of gas on the suction side (6) avoiding a return of the discharged air .  7) Device according to claim 1, characterized in that the lateral rotors (2) are provided at their ends with flanges (11) of diameter slightly greater than that corresponding to the tip of the partitions (5).  8) Device according to claim 1, characterized in that these three rotors of diameters chosen in simple ratios are synchronized with each other by gear discs (12) on one of their ends while the lateral rotors (2) can be connected to each other directly by a belt because they have the same direction of rotation.  9) Device according to claim 1, characterized in that the housing (3) consists of 2 symmetrical blocks along the plane of the axes of the rotors, each comprising a suction opening (6) and a discharge opening (7) on which are fixed the suction (14) and discharge (15) conduits adapted to the specific application of the device.