FR2599437A1 - Duct inducing nozzle. - Google Patents

Abstract

Nozzle combining a venturi tube 1 with a ventilation channel casing 2 comprising a branch 4 characterised by the fact that the throat of the venturi tube 3 is perforated with openings and may be improved by a perforated adjustment ring 5. This nozzle rectifies the dynamic pressure required at the point of intersection of an attached channel in the event of simultaneous flows in the main channel without changing the characteristic of the ventilation installation. It makes it possible to improve the characteristics of a ventilator in the event of having to increase its flow rate within the scope of the application to a "controlled air extraction" installation.

Description

 The invention relates to a device for driving a secondary air stream leading to the periphery of the throttle of a venturi. The constriction through which the primary air passes is of sufficient length to define the necessary passage section of the secondary air stream between the converging and the diverging. At the converging, the static pressure remains equal to that of the grafted pipe.

The * nozzles * type instrument compensates for the loss of flow (loss of pressure) in a pulsed aeraulic circuit with discontinuous operation onto which a second circuit is added, also provided with a fan - with continuous operation. (fig. 1 and 2)
The device comprises a venturi (1) placed on the discontinuous main circuit (2). According to a main characteristic of the invention, the throttle (3) of this venturi is perforated to allow the flow of the flow from the continuous grafted circuit (4), ending in a peripheral chamber to the perforated conduit and extending over a length sufficient for define the passage section necessary for the flow rate of the grafted pipe. The peripheral chamber is closed externally by a preferentially conical envelope connecting the external flanges of the converging and diverging of the venturi. On this envelope opens the grafted pipe oriented in the direction of flow of the fluid. An openwork ring (5) following a radial hole identical to that of the throttle allows the pressures to be adjusted. According to another non-mandatory characteristic, a valve (6) can be provided on the main pipe upstream of the venturi to close the discontinuous air circuit during stops to avoid parasitic phenomena.

Among the applications
Among the most interesting applications of the invention one can cite the intervention circuits to lower a chamber temperature and the so-called Controlled Aeration circuits II
In the "venturi" devices existing to date, the fluid flowing in the grafted pipe imparts the movement necessary for the entrainment of the fluid of the main pipe.

In the proposed system, the principle is reversed.

 In addition, in the prior systems, the static pressure in the grafted line was variable depending on the desired flow of the fluid. The proposed nozzle makes it possible to obtain a constant pressure in this pipe at the point of convergence.

 According to the description given above, the lights provided in the venturi throttle are used for the passage of the fluid coming from the grafted pipe.

 These lights consist of circular or square, oblong orifices arranged along the generatrix of the constriction.

The drilling axes are * rodXudx relative to each other or in parallel lines and, or crossed with respect to the axis of the nozzle. Without the venturi cone or the ring carrying the lights, the operation would be as follows:
- Nominal constant flow rate of the grafted line when the inlet fluid valve in the main line is closed
Constant reduced flow of the grafted line when the fluid is admitted into the main line (puvert valve)
With the proposed system, operation becomes
- Nominal constant flow rate of the grafted pipe (adjusted flow rate of the ring placed on the throttle of the venturi) when the intake fluid valve in the main pipe is closed.

 Nominal constant flow rate of the grafted pipe maintained by the vacuum created in the peripheral ring of the throttle receiving the fluid from the grafted pipe, when the fluid is supplied into the main pipe.

 The principle of the device being based on the phenomenon of depression created by the cone venturi, the ring is used to balance the static pressure, grafted pipe side, at the same value as that prevailing upstream of the convergent of the main pipe receiving the fluid periodically, serving as an inductor.

The device can replace the function of a motorized valve controlled by a differential pressure sensor, interposed on the grafted line, this regulation having to correct the dynamic pressure necessary in the event of simultaneous flow of fluid in the 2 lines. (Fig. 2)
The assembly without venturi cone corresponds for the common section to a parallel connection of 2 fans V 1- V 2 at point I. (see figure 4
For fan V 1 of the grafted pipe, with reference to FIG. 3 relating to mounting with and without operation of fan V 2
The increase in the characteristic of the installation I
(pressure drop) results in a sliding of the theoretical curve of the fan C 2 towards an intermediate point on C 3 between
the one above (C 2) and fan duct curve bypass
(C 1) operating alone.

 The cone mounting, where the diameter of the pipe D is greater than D 'D "results in a modification of the characteristic of the installation (less pressure drop of the fatt of the depression created for an equivalent air flow) Referring to FIG. 5, the repercussion on the theoretical curve of the (V) fan results in a shift from M to N lower total pressure, increase in flow rate.

With reference to FIG. 6, the corresponding increase in electrical consumption can be compensated for by better fan connection.
This last observation makes it possible to envisage the use of the highly constricted cane d to modify the characteristics of an installation (on which the regulation described here above is not necessary) by doubling or tripling the flow rate in the line grafted at the time. where the fan is put into service Empties the main line. This last use requires checking the dimensioning of the fan motor V 1 blowing in the branch line. This last use of the cone (to increase the flow rate of one of the fans) can be used on air extraction installations say "controlled ventilation".

The derived fan V 4 provides the minimum flow extraction function, the two fans V 1 - V 2 coupled with the maximum. In this case, the fan V 1 of the branch line, when operating alone, drains the network of rooms to be aerated constantly at minimum flow rate (WC- Sanitary- etc.)
The main line fan is activated when the premises it drains are occupied (bedrooms, living room, kitchen). Its operation changes the characteristics of the fan of the bypass line, which results in superior ventilation of the rooms it ventilates (WC, Sanitary). The new regulations are then respected.

 In this configuration, the 2 fans are placed on the terrace downstream of the suction duct networks of the ventilated rooms. The nozzle is placed at the intersection of the discharge of the primary and derived duct fans.

Claims (4)

 l.Tuyère associating a venturi (1) with an air duct casing (2) comprising a bypass (4), characterized in that the throttle of the venturi (3) is perforated with lights, making it possible to correct the necessary dynamic pressure at the intersection of the grafted pipe in case of simultaneous flow of fluids in the 2 pipes.  2.Tuyère according to claim 1 characterized by an adjustment ring (5) perforated according to a drilling identical to the throttle of the venturi.L'embrait improves the characteristics of a fan placed on the grafted pipe (4) if it is necessary to increase the flow rate of this fan, when the main line fan is put into service.  3. Nozzle according to claim 2 characterized by a shutter valve (6) disposed on the main pipe upstream of the venturi.  4.Application of the nozzle according to claims 1 and 2 to the production of an air extraction installation with "controlled ventilation" where the bypass fan ensures the extraction of minimum flow and the 2 fans coupled, that maximum.