SE534896C2 - Flow restrictors and method of reducing a flow resistance - Google Patents

Description

Liquids such as gases, e.g. in flow regulators to fans. Examples of fan applications can be read in patents US 5,265,594 and SE 529,989.

U.S. Pat. No. 5,265,594 describes how a flow restrictor through a gas duct upstream of a control valve is used to measure the gas flow.

Patent SE 529,989 describes how a flow restrictor through a gas channel downstream of a control valve is used to measure the gas flow.

Flow restrictors can be achieved in several different ways, e.g. by allowing the fluid to pass through one or more narrow pipes, different types of nets, sintered fluid-permeable pipes or gaps.

U.S. Pat. No. 4,006,634 discloses a flow meter consisting of a differential pressure gauge and a variable flow restrictor which decreases with increasing flow.

In this invention, the flow restrictor consists of a foil with radial slits so that they form a number of circular segment-shaped flaps. At a large flow, the flaps bend, and the flow resistance decreases. Since it is difficult to produce extremely thin slits in a foil, this means that the flow resistance is relatively small with a design like this, and that it thus becomes difficult to measure low flows.

An object of the present invention is to provide a greater initial flow resistance than in a design which utilizes flaps to bend at large flows as in patent US 4,006,634.

Another object of the invention is to provide a device with flow restriction which has a reduced flow resistance at large flows. This is important to remove increased flow resistance caused by turbulence and to increase the dynamic flow range.

By designing the geometry of the device according to the invention for the mentioned geometries, it is possible to make a flow restrictor in accordance with the invention. Summary of the Invention These objects are achieved by the apparatus and method of the appended independent claims, wherein particular embodiments are addressed in the dependent claims.

The present invention thus seeks in particular to counteract, improve or eliminate one or more of the above-identified shortcomings and disadvantages in conventional technology, individually or in any combination, and at least partially solves the above-mentioned problems by providing an equipment according to the appended claims.

According to one aspect of the invention, a variable flow restrictor is provided. The variable flow restrictor has a flexible foil with movable parts, and a fluid permeable body. The flexible foil is arranged adjacent to the fluid-permeable body, the movable parts being biased against the fluid-permeable such as flexible flaps; the body so that a variable fluid passage through the flow restrictor results by increasing movement of the flexible parts with increased flow through the fluid permeable body and the flexible foil.

In order to achieve a reducing flow resistance with increased flow, a thin flexible foil with flaps is placed close to the fluid-permeable body. By tightening the flaps, a high flow resistance is created at small flows which are then reduced as the flow increases. Preferably, the flexible film is placed adjacent to the fluid permeable body by bending and positioning with its convex side against the fluid permeable body. The flexible foil can be designed as a cone, partial cone or as a cylinder. The whole structure has a tube geometry whose cross section can be circular and or elliptical and / or polygonal.

This can be done according to an embodiment by placing a foil with flaps downstream next to a fixed flow restrictor in the form of a net or other fluid-permeable material. 53 15 896 An advantageous embodiment of the invention is to leave said flaps biased against the fixed flow restrictor. This method ensures that the flow resistance is maximized at low flows. An advantageous way of achieving this prestress is to bend the foil with flaps, and that the convex side lies against the flow restrictor which has a matching shape. The flaps will then be biased against the flow restrictor.

The bend on the foil can be of any shape, cone, sphere or cylinder. for example A further advantageous embodiment of the invention is that the flow restrictor is provided with holes or thinned material where it is covered by said flaps.

In some embodiments of the variable flow restrictor, the fluid permeable body has fluid permeable openings below the flaps.

By inserting these openings or piles, which can also be thinners of the material, the effect of the variable flow restrictor increases by reducing the flow resistance more at large flows.

In some embodiments of the variable flow restrictor, a differential pressure gauge is connected upstream of the fluid permeable body and downstream of the flexible film.

In a second aspect, the invention includes a method of reducing the flow resistance at increased flow in a flow restrictor. The method comprises biasing movable members such as flexible flaps on a flexible film by placing the flexible film adjacent a fluid permeable body thereby creating a variable flow restrictor by moving the movable members increasing with increasing fluid flow, which provides a variable fluid residual flow through.

The advantages of this method are as for the equipment described above. To provide a flow restrictor which has a reduced flow resistance at increased flow. Among other things, this is important to remove increased flow resistance caused by turbulence and to increase the dynamic flow range.

Flow resistance refers to the flow resistance as opposed to a pressure drop. General Description of the Drawings These and other aspects, features and advantages of the invention are at least partially apparent and specified by the following description of embodiments of the present invention, taken in conjunction with the accompanying figures, in which: Figure 1 shows in a schematic view an exemplary embodiment; foil with cut-out flap structures 10; Figures 2-4 show in a schematic view an exemplary embodiment a curved foil 21 and a flow restrictor 20; and Figure 5 shows in a schematic view an embodiment in which the flow restrictor 50 is provided with holes at the area under the flaps 52.

Description of embodiments Figure 1 shows in a schematic view a foil 1 with cut-out flap structures 10. The foil can be applied to a flow restrictor, which is described below.

A flow restrictor has a certain permeability to a fluid such as a gas. A solid flow restrictor may, for example, be provided in the form of a mesh, sintered metal or ceramic of a certain pore size or cell size, or other fluid permeable material. Flow restrictors are used, for example, in flow meters to create a pressure drop with the desired profile. A differential pressure across the flow restrictor can be measured and provides a measure of the flow.

Figure 2 shows in a schematic view an embodiment with a part of a curved foil 21 and a part of a flow restrictor 20 with a shape matching the contour of the foil 21. In this case, the flow restrictor and the foil are cylindrical. Here is shown what the radially outwardly bent flaps 22 in the untensioned state look like before the flow restrictor 20 is mounted together with the foil 21.

Figure 3 shows the curved foil 21 and the flow restrictor 20 having a shape matching the contour of the foil 21 assembled. Here, the flaps 32 abutting the flow restrictor 20 are shown in a biased condition.

Figure 4 shows the curved foil 21 and the flow restrictor 20 with a shape fitting with the contour of the foil 21 when a flow, 4, passes through the flow restrictor 20 and the downstream arranged foil 21. Here is shown how the now radially inwardly curved flaps 42 are bent by a large flow, Figure 5 shows in a schematic view an embodiment where the flow restrictor 50 is provided with holes 53 at the area illustrated by the arrows in Fig. shown by the arrows. under the flaps 52 according to a principle of the invention. Here is shown how the flaps 52 are bent by a large flow, passing the holes in the flow restrictor 50, shown by the arrows.

An example of a device in Figure 5 in accordance with the invention is obtained by a fluid flow illustrated by arrows flowing through a flow restrictor 50 and further whose flaps 52, which are an integral part of the foil 50 at large flows, bend downstream and thus open up. the area of the flow restrictor 50 so that the flow resistance is reduced.

Alternatively, the flow restrictor may be formed with thinned material or larger pore size or cell size or filter density where it is covered by said flaps. downstream through a foil 21, or in combination with the holes 53,

Claims (1)

10 15 20 25 30 35 534 896 7 PATENT REQUIREMENTS A variable flow restrictor, comprising - a flexible foil (21) with movable parts such as flexible flaps (22, 32, 42, 52); - a fluid permeable body (20, 50); wherein the flexible foil (21) is arranged adjacent to the fluid-permeable body (20, 50), wherein the flexible foil (21) is curved and has a convex side, and where the flexible foil (21) is placed with its convex side towards the fluid permeable body (20, 50), the movable parts being biased towards the fluid permeable body (20, 50) so that a variable fluid passage through the flow restrictor is achieved by increasing movement of the movable parts with increased flow through the fluid permeable body (20, 50). 50) and the flexible foil (21). . The flow restrictor according to claim 1, wherein the foil (21) is located downstream of the fluid permeable body. The flow restrictor according to any one of claims 1-2, wherein the flexible foil (21) is shaped like a cone. The flow restrictor according to any one of claims 1-2, wherein the flexible foil (21) is formed as a partial cone. The flow restrictor according to any one of claims 1-2, wherein the flexible foil (21) is formed as a cylinder. . The flow restrictor according to any one of claims 1-5, wherein the fluid permeable body (20, 50) has 10. ll. 534,895 fluid-permeable openings (53) adjacent the movable parts of the foil (21). The flow restrictor according to any one of claims 1-5, wherein the fluid permeable body (20, 50) has thinned material or larger pore size or cell size or filter density adjacent the movable parts. . The flow restrictor according to any one of claims 1-7, wherein the structure has a tubular geometric cross section which is circular, polygonal or elliptical. The flow restrictor according to any one of claims 1-7, wherein the construction has a tubular geometric cross section which is a combination of circular and / or elliptical and / or polygonal. The flow restrictor according to any one of claims 1-9, wherein a differential pressure gauge is connected upstream of the fluid permeable body (20, 50) and downstream of the flexible foil (21). A method of reducing a flow resistance at an increased flow in a flow restrictor, which comprises biasing movable members such as flexible flaps (22, 32, 42, 52) on a flexible foil (21); this is achieved by bending the flexible foil (21) so as to create a covex side and placing the flexible foil (21) with its convex side next to a fluid permeable body (20,50) creating a variable flow restrictor by moving the movable parts increasing with increased fluid flow, which provides a variable fluid flow through the flow restrictor.