SE454723B - CRYSTAL FLUID DIVISIONS - Google Patents

Description

20 25 30 35 40 454 723 2 In addition, the pulsating liquid flow causes the flow rate to irregularly increase or decrease relative to a predetermined flow rate, so that no satisfactory flow dividing function can be achieved.

In view of the above, the object of the present invention is to provide a flow-splitting structure which substantially eliminates the above-mentioned and other problems of conventional flow-splitting pipe constructions.

The invention is described in more detail below with reference to the accompanying drawings, in which Fig. 1 is a front longitudinal sectional view of a preferred embodiment of the present invention; Fig. A side longitudinal sectional view of the preferred embodiment; Fig. 3 is a sectional view taken along the line III-III in Fig. 1; Fig. 4 is a front longitudinal sectional view of a conventional flow dividing tubular structure; and Fig. 5 is a side longitudinal sectional view of the structure of Fig. 4.

A preferred embodiment of the present invention will now be described in detail with particular reference to Figs. 1-3.

The flow dividing structure according to the present invention comprises a main pipe 5, a pair of first branch pipes 6 (6a and 6b), whose inner diameter D2 is smaller than the inner diameter D1 of the main pipe 1 and which are branched from the main pipe 1 in such a way that their axes Ba and Eb intersect the axis of the main pipe 5, and a second branch pipe 7, the inner diameter D3 of which is at most equal to the inner diameter D2 of the first branch pipes Ba and Gb and whose axis intersects the axes of the first branch pipes 6a and 6b. A spherical guide surface B which is continuously connected to the inner wall surface of the main tube 5 is defined by the inner surface of the connecting portion between the main tube S, the first manifolds Ba and Gb and the second manifold 7, so that the liquid flowing along and near the inner surface of the main tube 5 is guided into the first branch tubes 6a and Gb.

As described above, the first manifolds Ba and fib are branched from the main pipe 5, so that they intersect one end Sa of the main pipe 5 and their axes may be inclined at a certain angle (the first branch pipes Sa and Bb are shown coaxial with each other in fig. 1-3). As best shown in Fig. 1, the axes of the first manifolds 6a and Bb extend eccentrically to the midpoint 0 of the end Sa 5 of the main pipe 5, so that a part of the outer peripheral surface of each of the the first manifolds Ga and 6b are exposed from the end Sa of the main pipe. The inner diameter D2 of the first manifolds 6a and 6b is smaller than the inner diameter D1 of the main pipe 5 and the diameter ratio (D2 / D13 is eg 0.67.

The second manifold 7 is connected to the exposed portions of the first manifolds Sa and Bb and intersects them.

The inner diameter D3 of the second manifold 7 is substantially equal to or smaller than the inner diameter D2 of the first manifolds Sa and Gb and this diameter ratio (D3 / D2) is e.g. 0.96.

The guide surface 8 has a hemispherical surface with a diameter equal to the inner diameter D1 of the main tube 5 and the guide surface 8 is continuously connected to the inner wall surface of the main tube 5.

As described above, the first and second manifolds 6a, 6b and 7 are branched from the end 5a of the main pipe 5, so that, as best shown in Figs. 2 and 3, the remaining surfaces of the first manifolds 6a and Bb, which are cut by the second the manifold 7, extends (in the upward direction in Fig. 2) from the main pipe and the initial surfaces 9 (Sa and Qb) continuously connected to the guide surface B.

In the flow-dividing construction described above, the liquid flowing out of the main pipe 5 is thereby divided uniformly into the first and second branch pipes Sa, Gb and 7 and the pulsation in the second branch pipe 7 can be prevented.

More specifically, when the fluid layer flowing at a relatively low velocity along and near the inner surface of the main tube 5 reaches the end tube 5 of the main tube 5, it is directed along the guide surface B towards the axis of the main tube 5 and to the initial surfaces 9a and Qb indicated by arrows in FIG. 1-3. The liquid flows directed towards the initial surfaces 9a and Qb are controlled into the first manifolds Sa and 6b by the initial surfaces Qa and Qb. As a result, almost the entire slowly flowing liquid layer is directed into the first manifolds 6a and Gb, while the liquid flow flowing into the second manifold 7 is the liquid flow flowing along and near the axis of the main pipe 5. As a result, the liquid is controlled to flow into the second manifold 7 at a uniform flow rate and the pulsation in the second manifold 7 can be prevented.

The guide surface B has hitherto been described as consisting of a part of a sphere, but it is understood that the present invention is not limited thereto and that the guide surface 8 may consist of a part of an ellipsoid or cone. In addition, the first manifolds Ba and 6b have been shown coaxial, but it is understood that, as shown in Fig. 3, the axes of the first manifolds Sa and Gb may be inclined relative to each other at an angle indicated by dashed lines.

The shapes and dimensions of the components of the structure described above are not intended to indicate the limits of the present invention, and it will be readily apparent to those skilled in the art that they may be suitably modified for particular environments and operating conditions.

As described above, in the cross-shaped flow-dividing tube structure of the present invention, a liquid layer flowing along and near the inner wall surface of a main tube is etched into the first manifold, which intersects the main tube at right angles and is prevented from flow into a second manifold coaxial with the main pipe so that the liquid flowing through the second manifold can be prevented from pulsing. Thereby, the liquid flowing out of the main pipe can be uniformly divided into the first and second branch pipes, so that the liquid can flow through each branch pipe and into a device connected thereto with a stabilized flow rate.

Claims (4)

10 15 20 25 5 454 723 Patent claim Flow-dividing cross-shaped manifold construction, including hydrogen-supply main tubes (5), a pair of hydrogen-conducting manifolds (Sa, Gb), which cut the main tube and are smaller in diameter than the main tube, and a hydrogen-conducting second manifold (7), which extends separates from the main pipe, the front branch pipes cut and have at most the same inner diameter as the first branch pipes, characterized in that the inner surface portion connecting the main pipe (5) with the front and second branch pipes (Sa, 6b and 77, respectively) has one from the main pipe pipe end continuously degrading curved shape for guiding liquid-like flowing along and in the vicinity of the main pipe (5) inner surface into the undertone branch pipes (Ga, öb). Manifold construction according to claim 1, characterized in that the inner surface portion (8) has a spherical shape with a curvature diameter equal to the inner diameter of the main pipe (5). Manifold construction according to claim 1, characterized in that the inner surface portion has an ellipoid shape. Branch pipe construction according to claim 1, characterized in that the inner surface portion has a partially conical shape.