NL2019555A - Flow meter - Google Patents

Abstract

A flow meter 1 has a housing 3 provided with an inlet part 3A and an outlet part 3D, as well as a widened part between them. This widened part consists of a guide part 3B connecting to the inlet part and a measuring part 3C connecting to the outlet part. There are a number of helical guide blades 5 with a core 7 inside it. The measuring part 3C is provided with a measuring chamber 9 in which a measuring ball 13 can rotate in a circle. No wall parts are present between the core 7 and the end face 11 of the outlet part 3D facing the measuring chamber. This allows fluid to flow freely from the measuring chamber. To make the fluid flow as constant and fluid as possible, the core 7 is solid with a flat end 7A.

Description

Flow meter DESCRIPTION:

FIELD OF THE INVENTION

The invention relates to a flow meter comprising: a housing provided with an inlet part and an outlet part, as well as a widened part therebetween comprising a guide part connecting to the inlet part and a measuring part connecting to the guide part and the outlet part, helical guide blades present in the guide part which are connected to the housing, a core present within the guide blades, a measuring chamber present within the measuring part, which is bounded on the outside by the measuring part of the housing, bounded on an inlet side by the guide blades, on a running side opposite the inlet side is bounded by an end face of the outlet part facing the measuring chamber, and is partially bounded on the inside by a core, and a measuring ball present in the measuring chamber, which ball runs around the end face in the measuring chamber during use, wherein between a measuring chamber adjacent to the measuring chamber end of the core and the after an end face of the outlet part facing the measuring chamber is present and no wall parts are present, wherein the distance between the outer edge of the end of the core adjacent to the measuring chamber and the inner edge of the end face of the outlet part facing the measuring chamber is smaller than the diameter of the measuring ball and in which the inlet part, the guide part and the measuring part of the housing, as well as the guide blades and the core (together) are one injection-molded part.

During use, the flow meter is installed between two pipe sections and liquid or gas flows via the inlet into the part with the helical blades, where the fluid is brought into rotation, and from there into the measuring chamber, where a measuring ball is put into rotation, and then via the outlet outside. The rotation speed of the measuring ball is a measure of the flow speed of the fluid.

The rotational speed of the measuring ball is, for example, measured with the aid of a light beam which is steered through the housing and is detected at an opposite location. The number of detected interruptions of the light beam (by the bullet) is a measure of the flow speed.

State of the art

Such a flow meter is known from WO 2015/065187 A. In the case of a flow meter with a middle part widened between the inlet part and the outlet part and containing a measuring chamber with a rotating measuring ball, it serves for a gradual inflow of fluid into the guide blades, in order to maintain a sufficient high flow velocity for carrying the bullet and for the career of the bullet a relatively broad core must be present. For injection-molding reasons, the core of this known flow meter is hollow and the core is open on the outlet side.

Summary of the invention

It is an object of the invention to provide a flow meter of the type described in the preamble with a higher measurement accuracy and better reproducibility of the measurements than that of the known flow meter. To this end, the flow meter according to the invention is characterized in that the core is solid. It has been found that the fluid flow through the flow meter in the case the core is solid, is more constant than in the case that the core is open on the outlet side. As a result of this more constant flow, the measuring ball is also entrained in a more constant manner by the fluid flow, resulting in a more accurate and more reproducible measurement result. With the known flow meter, the core is hollow and the end face of the core facing the outflow opening is open. It has been found that the shape of the end of the core facing the outlet part influences the flow of the fluid. By designing the core in a solid manner so that the said end face is closed, less turbulence occurs, as a result of which the flow at the path of the measuring ball is not affected and thus the movement of the measuring ball in the path is more constant, resulting in a greater measurement accuracy and better reproducibility than with the flow meter known from WO 2015/065187 A. It is also prevented that bacteria and / or other particles that are present in the liquid may adhere to the open part of the core by swirling the liquid.

It is noted that from JP S59-153124 A a flow meter is known for measuring the flow rate of liquid. This known flow meter also has a core, but the shape of the end of this core, beyond the measuring ball, does not have the effect of increasing the accuracy of the measurement by means of the measuring ball, because in the known flow meter the measuring ball is not located on the outlet side of the flow meter. An effect of the core in the known flow meter on the liquid flow and / or the measurement accuracy has not been described. Moreover, with this known flow meter, the housing at the location of the guide part and the measuring part is not widened. In the known flow meter, in contrast to the flow meter according to the invention, the trajectory of the measuring ball is present at a distance from the underside of the solid core, so that the shape of the core on the outlet side has no effect on the movement of the measuring ball. The arrangement of this known flow meter differs from the construction of the flow meter according to the invention due to the deviating housing and the deviating position of the measuring ball.

Furthermore, DE 2910387 A discloses a flow meter with a core which has a conical shape on the inlet side and on the outlet side. With this known flow meter, the measuring chamber is not limited by the outer wall of the housing, such as with the flow meter according to the invention, but there is a circular flow channel between the measuring chamber and the housing. As a result, in the known flow meter the liquid flows in a large diameter into the measuring chamber and the liquid leaves the measuring chamber at a smaller diameter through an outlet opening which is narrowed by a conical core part (2) and an opposite part (3), this in contrast to the flow meter according to the invention, wherein the liquid leaves the measuring chamber through a large outflow opening on a large diameter. Moreover, even in this known flow meter, the measuring ball is not located on the outlet side of the flow meter at the end of the core. An effect of the core of the known flow meter on the liquid flow and / or the measurement accuracy has not been described. The arrangement of this known flow meter and the function of its core deviate from that of the flow meter according to the invention.

From EP 0 172 451 A a flow meter is known which also has a core. With this known flow meter no broad core is used as with the flow meter according to the invention which through a large diameter leads the liquid out to bring the liquid to maximum radial rotation. The core in the known flow meter has a diameter that is much smaller than that of the core of the flow meter according to the invention. As a result, with this known flow meter, the shape of the core has hardly any effect on the liquid flow, let alone the measurement accuracy.

The space between the core and the outlet part is preferably completely open in the flow meter according to the invention. With a completely open passage between the core and the housing at the location of the outflow opening, the fluid flow is hardly disrupted.

A favorable embodiment of the flow meter according to the invention is characterized in that the end of the core is flat.

In an embodiment of the flow meter according to the invention, in which the end of the core is flat, the side wall of the core runs parallel or substantially parallel to the longitudinal direction of the flow meter.

A further embodiment of the flow meter according to the invention, in which the end of the core is flat, is characterized in that the side wall of the core towards the outlet part is not tapered parallel to the length direction of the flow meter, but tapered in the direction of the outlet part .

A still further embodiment of the flow meter according to the invention is characterized in that the guide blades are each provided with an inlet end adjoining the inlet part and an outlet end adjoining the measuring chamber which is provided with a recess with an arcuate boundary wall, the maximum distance between an end face of the outlet part facing the measuring chamber and this arc-shaped boundary wall is larger than the diameter of the measuring ball and the minimum distance between the end face of the outlet part facing the measuring chamber and this arc-shaped boundary wall is smaller than the diameter of the measuring ball. As a result, the fluid flowing out of the guide blades flows directly into the rotation path of the measuring ball, whereby a high measuring accuracy and good reproducibility is obtained. Because this arc-shaped or circular recess in the blades reduces the distance from the measuring ball to the blades, the measurement accuracy and reproducibility increase even more.

Brief description of the drawings

The invention will be explained in more detail below with reference to an exemplary embodiment of the flow meter according to the invention shown in the drawings. Figure 1 shows a section of an embodiment of the flow meter according to the invention.

Detailed description of the drawings

Figure 1 shows a cross-section of an embodiment of the flow meter according to the invention. The flow meter 1 has a housing 3 provided with an inlet part 3A and an outlet part 3D, as well as a widened part between them. This widened part consists of a guide part 3B connecting to the inlet part and a measuring part 3C connecting to the guide part and the outlet part. In the guide part there are a number of helical guide blades 5 which are attached to the housing with the outer edges. Inside these guide blades there is a core 7 which is attached to the inner edges of the lower parts of the guide blades.

Within the measuring part there is a measuring chamber 9, which is bounded on the outside by the measuring part 3C of the housing, and on an inlet side is bounded by the undersides 5C of the guide blades. On a running side opposite the inlet side, the measuring chamber is limited by an end face 11 of the outlet part facing the measuring chamber. Between the core 7 and the end face 11 of the outlet part facing the measuring chamber there is an opening that forms the outflow opening of the fluid from the measuring chamber. A measuring ball 13 is located in the measuring chamber, which ball runs around the end face 11 in the measuring chamber during use.

During use, fluid flows through the inlet bounded by the inlet member 3A into the blades section bounded by the guide member 3B, where the fluid is rotated by the helical blades 5. Upon exiting the blade section, the fluid flows directly into the through the measuring member 3C limited measuring chamber 9, where the measuring ball 13 is brought into rotation. The fluid then flows out via the outlet bounded by the outlet part 3D. The rotation speed of the measuring ball is a measure of the flow speed of the fluid. In figure 1 arrows 21 indicate the flow of the fluid.

No wall parts are present between an end 7A of the core 7 adjacent to the measuring chamber 9 and the end face 11 of the outlet part 3D facing the measuring chamber. The space between the core 7 and the outlet part 3D is completely open. This allows the fluid to flow unhindered from the measuring chamber to the outlet, so that the flow resistance of the flow meter is low. To prevent the measuring ball 13 from being able to get out of the measuring chamber 9, the distance 15 between the outer edge 7B of the end 7A of the core adjacent to the measuring chamber and the inner edge 11B of the end face 11 of the outlet part 3D facing the measuring chamber is smaller then the diameter D of the measuring ball 13. In order to make the fluid flow as constant and fluid as possible, the core 7 is solid and the end 7A of the core is flat.

The guide blades 5 are provided with an inlet end adjacent to the inlet and an outlet end adjacent to the measuring chamber. This outlet end is provided with a recess with an arcuate boundary wall 5C. The maximum distance 17 between the end face 11 of the outlet part facing the measuring chamber and this arc-shaped boundary wall 5C is larger than the diameter D of the measuring ball 13 and the minimum distance 19 between the end face 11 of the outlet part facing the measuring chamber and this arc-shaped boundary wall 5C is smaller than the diameter D of the measuring ball 13. As a result, the fluid flowing out of the guide blades flows directly into the rotation path of the measuring ball.

The inlet part 3A and the outlet part 3D both have an equally large cylindrical opening and are present in line with each other. The widened part (formed by parts 3B and 3C) has a larger outer diameter than that of the inlet and outlet part, the transition from the inlet part to the widened part not progressing abruptly with a step, but gradually through a conical wall part. The core 7 has a conical wall 7C facing the inlet, which gradually guides the axially directed incoming fluid flow 21 to the guide blades 5. In the relevant embodiment, the side wall 7D of the core tapers slightly towards the outlet.

Although in the foregoing the invention has been elucidated with reference to the drawings, it should be noted that the invention is by no means limited to the embodiment shown in the drawings. The invention also extends to all embodiments deviating from the embodiment shown in the drawings within the scope defined by the claims. Thus, the side wall of the core can also run parallel to the longitudinal direction of the flow meter instead of the tapered course shown in the drawings.

Claims (6)

A flow meter (1) comprising: a housing (3) provided with an inlet part (3A) and an outlet part (3D), as well as a widened part therebetween comprising a guide part (3B) connecting to the inlet part and a guide part connecting to the guide part and measuring part connecting the outlet part (3C), helical guide blades (5) present in the guide part which are connected to the housing, a core (7) present within the guide blades, a measuring chamber (9) present inside the measuring part and limited on an outside by the measuring part (3C) of the housing, bounded on an inlet side by the guide blades (5), on a running side opposite the inlet side bounded by an end face (11) of the outlet part (3D) facing the measuring chamber, and on an inner side is partially bounded by the core (7), and a measuring ball (13) present in the measuring chamber (9), which runs during use over the end face (11) in the measuring chamber, wherein between a (9) adjacent the end (7A) of the core (7) and the end face (11) of the outlet part (3D) facing the measuring chamber, an opening is present and no wall parts are present, the distance (15) between the outer edge being present (7B) of the end (7A) of the core adjacent to the measuring chamber and the inner edge (11B) of the end face (11) of the outlet part (3D) facing the measuring chamber is smaller than the diameter (D) of the measuring ball ( 13), and wherein the inlet part (3A), the guide part (3B) and the measuring part (3C) of the housing, as well as the guide blades (5) and the core (7) together form one injection molded part, characterized in that the core (7) is solid. A flow meter (1) according to claim 1, characterized in that the end (7A) of the core (7) is flat. A flow meter (1) according to claim 1 or 2, characterized in that the side wall (7D) of the core is parallel or substantially parallel to the longitudinal direction of the flow meter. 4. Flow meter (1) according to claim 1 or 2, characterized in that the side wall (7D) extends from the core to the outlet part (3D). Flow meter (1) according to claim 1, 2, 3 or 4, characterized in that the space between the core (7) and the outlet part (3D) is completely open. A flow meter (1) according to claim 1, 2, 3, 4 or 5, characterized in that the guide blades (5) are each provided with an inlet end adjacent to the inlet part (3A) and an inlet end adjacent to the measuring chamber (9). outlet end, which is provided with a recess with an arcuate boundary wall (5C), the maximum distance (17) between an end face (11) of the outlet part (3D) facing the measuring chamber and this arcuate boundary wall (5C) being larger than the diameter of the measuring ball (11) and the minimum distance (19) between the end face (11) of the outlet part (3D) facing the measuring chamber and this arc-shaped boundary wall (5C) is smaller than the diameter of the measuring ball (13).