FR2623618A2 - Device for sampling and measuring the flow rate of a liquid in constant or pulsed circulation - Google Patents

Abstract

Device for sampling and measuring the flow rate of a liquid according to the main patent, characterised in that the convex conical upper surface 9 of the male cone 8 has a vortex angle slightly larger than the concave conical lower surface 10 of the female cone 5, so as to make between the two a chamber 11 whose thickness decreases from the centre towards the periphery, this thickness being furthermore held at a minimum value using struts 12 carried by one of the cones. Main application in the dairy industry.

Description

Device for sampling and measuring the flow rate of a liquid in constant or pulsed circulation.

 The main patent describes a device for sampling and measuring the flow rate of a liquid in constant or pulsed circulation, in particular of a foaming liquid such as milk, this device comprising means for. realize a cylindrical laminar flow of the total flow, a means for taking a precise and constant fraction of this laminar flow and accumulating it in a sample receptacle, as well as a means for receiving and evacuating the rest of the laminar flow, and an electrical means to measure in real time directly in the receptacle the variation as a function of time of the volume of the sample, without taking account of the possible volume of the foam, and to deduce therefrom the variation as a function of time of the volume of the total flow.

 In particular, in a preferred embodiment of the invention, the cylindrical laminar flow was obtained from the incoming flow by expanding it between a fixed upper female cone, in the form of an inverted funnel, and a mobile lower male cone, the generators of which were parallel to those of the female cone, and which was mounted on a spring from a lower sliding rod to come to be applied at a short distance inside the female cone.

 Furthermore, proportional sampling was obtained by openings drilled obliquely in the wall along which and inside which the cylindrical laminar flow occurred. Finally, the flow measurement insensitive to the volume of foam was obtained by a capacitive measurement between a central cylindrical electrode and the external cylindrical wall of the receptacle.

 The purpose of this certificate of addition is to bring improvements to these various means of laminar flow, sampling and measurement in order to make the device more precise and more constant.

 The first improvement consists in choosing for the lower male cone mqbile an angle at the top of its convex surface slightly greater than the angle at the top of the concave inner conical surface of the female cone, in order to provide between the two a chamber whose thickness decreases from the center to the periphery, as the circumference of the flow increases. In addition, this male cone is mounted by means of a rod protruding at the top and sliding not in the base of the flow chamber, but in the upper part of the female cone for better centering, this rod being immobilized in translation and possibly in rotation relative to the male cone and to the female cone, the biasing spring also being placed in the upper position.

 A second improvement consists in replacing the simple sampling openings arranged in the wall by vertical slots extended inwards by close parallel walls whose upper edge is sharpened in the shape of a knife for a more precise sampling. These knives are preferably removable and mounted by simple spring.

 A third improvement consists in placing between the outer wall of the receptacle and the central measurement electrode, a metal tube leaving at its upper end a pressure equalization passage, and at its lower end one or more very small openings height allowing the measured liquid to pass by opposing the passage of the foam, the measurement then taking place between the central electrode, which is a simple metal rod covered with a dielectric insulator such as polytetrafluoroethylene, and said tube, and not more between the electrode and the outer wall.

Other features of the invention will appear in the following description of an embodiment taken as an example and shown in the accompanying drawing, in which
Figure 1 is an axial section of the device; and
2 shows, on a larger scale, an external view along II of one of the sampling knives.

 FIG. 1 shows the sampling chamber 1, with its flow wall 2 and its outer wall 3, and the fixed upper part 4 including the female cone 5.

 The liquid arrives via the nozzle 6 and ends in the axis of the female cone at 7 before flourishing between the female cone and the male cone 8, which, in accordance with this certificate of addition, has a angle at the top greater than that of the female cone 5, so as to form between the convex conical outer surface 9 of the male cone and the concave conical inner surface 10 of the female cone, a chamber 11 whose thickness decreases from the center towards the periphery, as the flow of the liquid arriving at 7 expands according to circumferences of increasing diameter. The minimum thickness of this flow at the periphery of the assembly is defined by spacers 12, for example three in number, located at 1200 from the axis, and which are for example fixed in the female cone 5 to serve as male cone stop 8.

 The male cone 8 is mounted by means of an axial rod 13 which protrudes at its upper part and slides at its upper end in a part 14 fixed to the upper end of the fixed part 4. The return spring 15 is disposed inside this part 14 and around the rod 13, and is supported on an end button 16, integral in translation and in rotation with the upper end of the rod 13, and preferably also immobilized in rotation relative to the part 14. The button 13 is for example of rectangular shape and enters a rectangular milling 17 practiced diametrically in the upper part of the part 14.Moreover, the male cone 8 is immobilized in translation, and is of preferably also in rotation relative to the lower end of the rod 13 by means of a bar 18 fixed by two screws 19 and 20, respectively on the end of the rod 13 and on the cone 8.

 In this way, the thrust of the spring 15 constantly controls the male cone 8 in abutment against the spacers 12. However, in the event of waterlogging, for example by the presence of agglomerations of cream particles, it is possible to release the flow by simply pressing button 16 at the top of the unit.

 From the periphery of the set of male 8 and female 5 cones, the laminar flow continues against the interior surface of the cylindrical envelope 2 of the flow chamber 1. This is where the removal of the precise fraction of the total flow of this flow. As in the main patent, apertures are used, preferably three in number, distributed at 1200 around the axis of the device to make the sample insensitive to small imperfections in the verticality of the device. However, each of these openings 21 is in the form of a slot oriented parallel to the generatrices of the cylinder 2 and extended towards the inside of the flow chamber 1 by a part 22 whose horizontal section is U-shaped, with two lateral wings 23 whose the upper edge 24, which is substantially horizontal, is sharpened as shown in FIG. 2 to cut out in the blade of the laminar flow a precise width corresponding to the spacing between the two sharp edges 24.

The assembly of each of these pieces 22 in the form of a double knife is mounted in one of the slots 21 from the inside of the wall 2, preferably in a removable manner, for example by means of a pin 25 and of a spring 26. The shape and the inclination of these parts 22 are such that they direct the flow taken towards the exterior of the wall 2.

 The fractions of the flow thus collected by the three knives 22 are conducted in the interval between the two walls 2 and 3, and from there flow through one or more openings 27 in the lower receptacle, constituted by a cylindrical wall 28 closed at its base by a bottom piece 29.

 The rest of the laminar flow, which constitutes the major part remaining after this sampling, flows into a suction chamber 30, in communication with the outlet nozzle 31, this communication chamber being at the base of the chamber. flow 1 with which it is connected, no longer by a simple orifice as in the main patent, but by a continuous circular slot 32 situated between the base of the cylindrical flow wall 2 and a central mushroom 33 with a conical upper surface , this mushroom 33 being fixed in the part 34 located between the flow chamber 1 and the receptacle 28.

 In the axis of this cylindrical receptacle 28 is arranged a measuring electrode 35, for example made of stainless steel coated with a dielectric such as polytetrafluoroethylene, to allow the capacitive measurement of the height of the liquid accumulated in the receptacle 28. However, instead of taking this measurement directly between the central electrode 35 and the outer wall 28, as in the main patent, it is preferable to have a metal tube 36 around this central electrode 35 to constitute the second measurement electrode. this fact, the outer wall 28 of the receptacle no longer needs to be metallic, and the foam formed by the flow of the liquid remains confined to the outside of the measurement cell formed by the electrodes 35 and 36, by providing for this a tube 36 devoid of any opening, except its upper opening 37, which opens at very short distance below the part 34, and one or more lower openings 38 of a height very low to allow the passage of the liquid by preventing the passage of the foam. In this way, the measurement is even more precise and more independent of the foam than in the device according to the main patent.

 Of course, after the measurement operation, the liquid accumulated in the receptacle 28 is discharged through the nozzle 39 of the bottom part 29 communicating with the base of the receptacle, both outside and inside the measuring tube 36.

Claims (6)

 1. Device for sampling and measuring the flow rate of a liquid according to the main patent, comprising a central supply (7) of the liquid blooming between a fixed external female cone (5) and a mobile internal male cone (8) for producing a cylindrical laminar flow inside a flow envelope (2) comprising orifices (21) ensuring the withdrawal of a precise and constant fraction collected in a receptacle (28), and a suction chamber ( 30) in communication with the flow chamber to collect and evacuate the non-withdrawn part of the flow, the measurement of the level of the withdrawn part in the receptacle being determined electrically by capacitive measurement using a central electrode ( 35),  characterized by the fact that the convex conical upper surface (9) of the male cone (8) has a slightly greater apex angle than the concave conical lower surface (10) of the female cone (5), so as to form a space between the two a chamber (11) whose thickness decreases from the center towards the periphery, this thickness being further kept at a minimum value by means of spacers (12) carried by one of the cones.  2. Device according to claim 1, characterized in that the male cone (8) is integral at least in translation with a rod (13) protruding at its upper end and sliding in a part (14) integral with the upper part (4) of the device, this rod being integral at least in translation with a button (16) located at its upper end and pushed axially upwards by a return spring <15), applying the male cone (8) against the spacers (12), while temporarily increasing the thickness of the chamber (11) for release by manual action on the button (16).  3. Device according to claim 2, characterized in that the rod (13) is also immobilized in rotation, both relative to the male cone (8) and relative to the button (16), and that the latter is him -same immobilized in rotation relative to the upper part (14) in which it slides.  4. Device according to one of the preceding claims, characterized in that each of the sampling openings (21) formed in the cylindrical wall (2) of the flow chamber (1) is extended inwards by a sampling piece (22) with a substantially very narrow U-shaped section, the upper edges (24) of the wings of which are in the form of knives with parallel sharp edges and at a small interval defining the fraction taken, the shape and the inclination of these parts directing the flow taken towards the outside of the wall (2) of the flow chamber (1), and from there towards the receptacle (28).  5. Device according to one of the preceding claims, characterized in that the flow orifice (32) between the flow chamber (1) and the suction chamber (30) is constituted by a narrow circular slot (32 ) formed between the wall (2) of the flow chamber and a central mushroom (33) with a convex upper surface secured to the base (34) of the suction chamber.  6. Device according to one of the preceding claims, characterized in that the central measurement electrode (35) is coated with a dielectric such as polytetrafluoroethylene, and surrounded by a metal measurement tube (36) devoid of orifice, except its upper orifice (37) located very close to the upper wall (34) of the receptacle (28) and used for balancing the pressures, and one or more lower orifices (38) located very close to the bottom part (29 ) of the receptacle (28), the height of these openings (38) being sufficient to allow the passage of the liquid and insufficient to allow the passage of the foam possibly formed by the flow, the capacitive measurement of the level of the liquid then being carried out between the central electrode (35) and said measurement tube (36).