WO1989004118A1

WO1989004118A1 - Device for counting discrete elements in suspension in a fluid medium

Info

Publication number: WO1989004118A1
Application number: PCT/FR1988/000556
Authority: WO
Inventors: Guy Rogues
Original assignee: Cerisy S.A.
Priority date: 1987-11-10
Filing date: 1988-11-10
Publication date: 1989-05-18
Also published as: EP0345314A1; FR2622971A1

Abstract

A device for counting discrete elements in suspension in a fluid medium (Mf) comprises a buffer reservoir (1) containing the fluid in which the discrete elements (Ed) are present in suspension. Means (2) for inducing turbulent flow are provided and means (3) for forming a stream of fluid are connected to said means for inducing turbulent flow. The means for inducing turbulent flow (2) and for forming a stream of fluid (3) make it possible to arrange each discrete element (Ed) in any colony of elements in suspension in a sequence of unique elements in this stream of fluid. Counting means are provided in the vicinity of the stream of fluid. Application to counting living organisms for example small fish in a fish-breeding tank.

Description

DEVICE FOR COUNTING DISCRETE SUSPENSION ELEMENTS

IN A FLUID ENVIRONMENT.

The present invention relates to a device for counting discrete elements suspended in a fluid medium.

The counting of discrete elements suspended in a fluid medium, such as in particular very large colonies of fry which may present several million individuals in a fish-farming basin, can only be carried out to date empirically and based on a very rough statistical calculation.

Although modern calculation techniques make it possible to envisage increasingly precise calculation details, data entry allowing the induction of a corresponding number of discrete elements remains very delicate and does not allow, in particular in the case of discrete elements constituted by living organisms, giving the colony to count an irreducible character of mobility, to obtain a counting assessment of great precision. The present invention aims to remedy the aforementioned drawbacks by the use of a device for counting discrete elements suspended in a fluid medium.

Another object of the present invention is to implement the device for counting discrete elements suspended in a fluid medium, which, in the case where the discrete elements are living organisms such as fry, can be easily integrated into schools or fish farms.

Another object of the present invention is finally the implementation of a device of very high reliability and requiring low maintenance costs.

The device for counting discrete elements in suspension in a fluid medium object of the invention is remarkable in that it comprises, a buffer tank of said fluid in which are located said discrete elements in suspension, means for swirling flow of a portion of said fluid contained in the buffer tank, means for forming a fluid flow stream connected to said means vortex flow, said vortex flow means and said means for forming a fluid flow stream allowing, from any colony of suspended elements, the ordering of each element in a successive file single element in said fluid flow stream, counting means of each element arranged in the vicinity of said fluid flow stream.

The device for counting discrete elements suspended in a fluid medium object of the invention finds application to the counting of discrete inert or slowly movable elements suspended in a fluid or mobile living organisms, such as fry or shells for example.

The device which is the subject of the invention will be better understood on reading the description below and on observing the drawings in which: - Figure la shows a view in longitudinal section of the device for counting discrete elements suspended in a fluid medium according to the invention,

FIG. 1b represents a top view of the device for counting discrete elements suspended in a fluid medium according to the invention,

the figure represents it, schematically, the operating principle of the device according to the invention, as represented in figure la,

FIGS. 2a, 2b and 2c show a detail of an embodiment of a means for swirling the fluid medium used in the device which is the subject of the invention,

- Figures 3a and 3b show by way of illustration a device for counting discrete elements suspended in a fluid medium, more particularly suitable for fish farming, - Figure 4 shows an illustrative diagram of a device for detecting and counting d 'discrete elements Ed by way of nonlimiting example, FIG. 5 represents a non-limiting embodiment of the means for detecting and counting the discrete elements Ed,

- Figure 6 shows a preferred, non-limiting embodiment of a device for counting discrete elements suspended in a fluid medium Mf more particularly suitable for counting living organisms such as fry.

- Figure 7a shows, in partial longitudinal section, a non-limiting embodiment of means for making vortex flow, - Figure 7b shows an explanatory diagram relating to Figure

7a,

- Figure S shows a particular embodiment of a device for counting fish larger than a few centimeters. The device for counting discrete elements suspended in a fluid medium which is the subject of the invention will be described firstly in conjunction with FIGS. 1a, 1b, le.

In accordance with the aforementioned figure, the device for counting discrete elements denoted Ed in FIG. La, suspended in a fluid medium, denoted Mf, object of the invention, comprises a buffer tank 1, the buffer tank comprising a reserve of fluid in which the discrete Ed elements are in suspension.

In addition, as shown in FIG. 1 a, the device for counting discrete elements Ed which is the subject of the invention comprises means 2 for whirling a portion of the fluid contained in the buffer tank 1 .

Means 3 for forming a fluid flow vein are connected to the means 2 for vortex flow, the means for vortex flow 2 and means 3 for forming a fluid flow vein allowing starting from any column of elements in suspension, the ordering of each element Ed, according to a successive file of unique elements in the vein of fluid flow.

It will of course be understood that the device for counting discrete elements Ed suspended in a fluid medium Mf according to the invention is based on the principle of the so-called Coriolis acceleration further acceleration. Indeed, the influence of the rotation of the earth manifests itself during the flow of a fluid in an orifice of circular section, where it is easy to note, for substantially regular flow conditions, that the fluid at level of the opening of the circular orifice begins to flow according to a vortex flow.

The discrete elements Ed suspended in the fluid Mf are then entrained by the vortex and the discrete elements Ed are accelerated in a constant manner and separate from each other before entering the fluid vein.

Means 4 for counting each discrete element Ed are arranged in the vicinity of the fluid flow stream in order to ensure a substantially regular counting of each discrete element Ed disposed in the fluid flow stream. Of course, the fluid flow stream located downstream of the vortex flow means 2 has a sufficient length so that, after a suitable travel distance, the flow in the fluid stream can be considered to be substantially laminar, the discrete elements Ed then being separated. In FIG. 1 b, there is shown a top view of the buffer tank 1 and the successive separation of the discrete elements Ed when these are entrained in the vortex flow.

In FIG. 1c, on the contrary, following the separation of the discrete elements Ed in the vortex flow region, these same discrete elements have been sequentially sequenced and separated substantially at the tail leu leu in the flow vein of fluid, which is then substantially in laminar flow.

As has been shown in particular in FIG. 2a, the means 2 for swirling a portion of the fluid Mf contained in the buffer tank 1 comprise at least one funnel 20 of conical type.

As shown in FIG. 2b and 2c, the means for swirling the flow 2 of part of the fluid contained in the buffer tank can also consist of at least one advantageously as a function of the acceleration conditions necessary for the separation of each discrete element Ed.

As shown in FIG. 1 a and in particular, the vortex flow means 2 also include a valve 21 symbolized by a tap, this valve of the solenoid type being able to be controlled simply upon opening and / or the closure. Thus, the only command at the opening of the valve 21 allows the fluid medium Mf contained in the buffer tank 1 to flow into a vortex. Furthermore, as shown in FIG. 1a, a nozzle 22 of crystal clear water supply is connected to a pump 23, the assembly of the nozzle 22 and the pump 23 allowing upon opening of the valve or solenoid valve 21 to supply the buffer tank 1 with a flow rate substantially identical to the flow rate of flow of the flow stream, this in order to maintain the height h of the fluid medium Mf, in the buffer tank l substantially constant. The height h of fluid medium Mf in the buffer tank I is of course determined in order to ensure vortex flow conditions and then flow conditions in the substantially laminar flow stream, practically regular, throughout the process of counting discrete elements Ed.

As can be noted in FIG. 1a, 1b, the, ies means 3 for forming a fluid flow stream connected to the vortex flow means are constituted by a nozzle or pipe aboucing at the level of the narrowest part of the funnel 20, downstream of the valve 21.

The tube or nozzle has at least one part transparent to electromagnetic waves in order to ensure the counting of the discrete elements Ed by means of an electromagnetic wave detector system as will be described below in the description. . An embodiment more particularly suitable for counting discrete elements Ed constituted by living organisms such as fry in the fish farming sector will be described in conjunction with FIGS. 3a and 3b. As shown in Figure 3a and 3b above, the means 2 for swirling flow can advantageously be constituted by at least one funnel, the most flared opening directly connected to the bottom of the buffer tank l. The funnels 20 are arranged vertically to subject the fluid part Mf of the buffer tank 1 under Corioiis acceleration and thus create a vortex flow.

As shown in Figure 3a and 3b, the funnels 20 can be arranged either at the bottom of the buffer tank 1 constituting a breeding basin, or laterally thereto, as shown in Figure

3b.

Of course, the device as shown in FIG. 3a or 3b can comprise several funnels in parallel or possibly several funnels in cascade. According to a particular embodiment, the tube 30 or nozzle having at least one transparent part consists of a glass tube transparent to visible light.

Given the embodiment of the tube 30 previously described, a more detailed description of the counting means 4 of each discrete element Ed will be given in connection with FIG. 4.

According to the aforementioned figure, the counting means 4 of each discrete element Ed arranged in the vicinity of the flow stream comprise means 40 for emitting electromagnetic radiation of determined wavelength, and means 41 for focusing "radiation on the part transparent to electromagnetic radiation of said tube 30 or nozzle.

In addition, means 42, 43 for receiving the electromagnetic radiation transmitted by the transparent part of the tube 30 or nozzle seat of the flow stream are provided. Detection and counting means 44 of the variation in intensity of the electromagnetic radiation transmitted during the passage through the flow vein of a discrete element Ed in suspension are also planned.

In an advantageous, nonlimiting embodiment, the means 40 for emitting electromagnetic radiation are constituted by a light-emitting diode. The focusing means 4 1 are constituted by a suitable lens or optics and the focusing means 42 are also constituted by a suitable optics.

The means 43 for receiving electromagnetic radiation can then advantageously be constituted by a photodiode or a phototransistor sensitive to the wavelength of the electromagnetic radiation considered.

The actual reception means 43 constituted by a suitably polarized photodiode or phototransistor are directly connected to the detection and counting means 44.

Without limitation, and by way of an advantageous example, the detection and counting means 44 may comprise a circuit element of the Schmidt trigger type delivering a calibrated signal for any variation in amplitude of the signal delivered by the photodiode or the phototransitor 43 greater than a determined threshold value and a counting circuit proper, making it possible to directly count the number of transitions delivered by the circuit of the Schmidt trigger type. Of course, the Schmid trigger type circuit can be followed by a differentiator circuit or a monostable circuit delivering pulses of very short duration.

As shown in addition in FIG. 4, the means 0, 41 for receiving and 42, 43 for electromagnetic radiation and the transparent area of the tube 30 or nozzle are enclosed in an opaque enclosure 45. This allows to guard against the effects of stray light likely to deteriorate the accuracy of the counting. A more detailed description of the means of detection and counting 44 of the variation in intensity of electromagnetic radiation will be given in connection with FIG. 5. According to the aforementioned figure, the detection and counting means 44 advantageously comprise amplifier means 40, 140 connected at the output of the reception means 43 for electromagnetic radiation and deliver an amplified signal. A threshold triggering circuit 441 constituted for example by the differential amplifier receiving a determined reference voltage, receives on the positive terminal for example the amplified signal delivered by the amplifier means 440 and makes it possible to generate for a variation in amplitude of the signal amplified above the threshold value V ef, a trigger signal denoted SD. A monostable circuit 442 is connected at the output of the threshold trigger circuit 441 and constitutes a rapid monostable circuit making it possible to generate a calibrated counting pulse for each discrete element Ed suspended in the flow stream. A counting circuit 443 proper receives the counting pulses and makes it possible to store the number of discrete elements Ed in suspension in the flow vein, the discrete elements thus being counted.

An embodiment more particularly suitable for counting discrete elements Ed constituted by living organisms such as fry, will now be described in connection with FIG. 6. In this case, the buffer tank 1 in its part opposite to the setting means in vortex flow of part of the fluid Mf, comprises ultrasonic transducer means, denoted 5, intended to cause the migration of the discrete elements constituted by the fry towards the vortex flow means 2. By way of nonlimiting example , the transducer 5 can emit uitrasonic waves in pulsed regime, the frequency of the uitrasonic carrier wave being between 40 and 100 kHz.

In addition, in the vicinity of the means 2 for whirling a portion of the fluid Mf into a vortex, there may be arranged means generating an electric field denoted 6. The electric field thus generated by the means 6 has a current density sufficient to cause a temporary inhibition of the motor reactions of the elements discrete Ed formed by living organisms, so as to prevent these from moving against the current of the swirling. The means 6 electric field generators can, in the case where the buffer tank 1 is constituted by a tank made of metallic material, simply comprise an electrode on the surface of the fluid medium Mf, this electrode, depending on the height h of fluid, being brought to a potential, preferably alternating, so as to create a field of inhibition between the electrode and the opening of the means 2 for making vortex flow of part of the fluid Mf. Finally, funnels and tubes or nozzles of different sizes can be provided, the opening of each funnel 20 leading to the level of the buffer tank 1, being provided for example with a calibrated sieve denoted 24.

In a nonlimiting embodiment, the calibrated screen 24 is constituted by a metal grid and the electrode 60 constituting means generating an electric field is placed above the calibrated screen 24 on the surface of the fluid medium Mf.

In addition, as also shown in FIG. 6, the internal wall of the funnels 20 can be provided with helical ribs in order to promote the whirling flow of the fluid medium.

The helical ribs are denoted 25 in FIG. 6.

The device for counting discrete elements previously described is satisfactory for counting discrete elements of small size, such as fry. However, in order to allow the counting of larger fish, that is to say larger than a few centimeters, a description of a more advantageous embodiment will be given in connection with FIGS. 7a, 7b and 8.

In accordance with FIG. 7a above, the means for swirling a portion of the fluid contained in the buffer tank comprises a separating cylinder 200. This separating cylinder allows a swirling flow with increasing acceleration of the fluid coming from the buffer tank and comprising the discrete elements in suspension in order to ensure the separation of the latter. As shown in partial section in FIG. 7a, the separating cylinder 200 comprises an inlet connection nozzle 2001, a chamber of revolution 2002 provided on its internal wall with a helix with variable pitch 2020, a nozzle outlet connection nozzle 2003. The inlet connection nozzle 2001, the outlet connection nozzle 2003 and the revolution chamber 2002 are mounted in leaktight manner. The enclosure of revolution 2002 is further mounted to rotate about its longitudinal axis of symmetry Λ, constituting longitudinal axis of symmetry of the separating cylinder 200. In addition, drive means 2004 in rotation of the enclosure of revolution 2002 are planned.

During the rotation of the enclosure of revolution 2002, the separator cylinder being, of course, supplied with fluid containing the discrete elements to be separated Ed, the fluid coming from the reservoir is subjected to a vortex flow causing an increasing axial acceleration of the fluid to bring about an axial separation of the discrete elements Ed in the direction of axial flow of the fluid. As soon as the discrete elements Ed enter the separating cylinder 200, they are subjected, on the one hand, to the centrifugal force due to the vortex flow of the fluid, this centrifugal force having the purpose of neutralizing the discrete elements Ed when these consist of relatively large fish. Then, the discrete elements Ed, directed by the centrifugal force towards the periphery of the separating cylinder 2002, are separated from the helical element by a cushion of water, but are subjected to the axial acceleration corresponding to the increasing pitch of the element helical, which prints a variable longitudinal flow speed of the fluid as a function of the position relative to the propeller for a given rotation speed of the cylinder 200.

Preferably, it will be noted that the radius r of the inlet connection nozzle 2001 is less than the radius R of the separating cylinder

2002 and, in particular, the aforementioned revolution enclosure 2002. The radial dimension h of the propeller is determined so that it checks the relationship:

R - r. he

Of course, the enclosure of revolution 2002 is preferably mounted in a sealed manner on the inlet connection nozzles 2001, respectively outlet 2003 by means of bearings 2005, 2006 or of bearings. In FIG. 7b, the development of a point on the edge of the helicoid is shown in planes in case A, where the helicoid has a constant pitch on a first, a second and then a third turn of the cylinder 2002 and, in case B, in the case where the pitch of the helix is variable and increasing, as shown in the above-mentioned figure. It will be noted that on the first turn, the axial displacement of the point considered is equal to a length xl, this same point moving by a length x2 during the second round greater than xl, then by a length x3 greater than x2 at during the third round and so on.

Discrete Ed elements made up of fish at the entrance to the separator cylinder can appear in several, at the same time. The rotating wave generated by the rotation of the helical element tends to separate them radially by the effect of centrifugal force, while neutralizing the latter due to the change of frame of reference, the fish being in fact subjected to the passage of a flow substantially laminar in the inlet connection nozzle 2001 to a vortex flow in the separating cylinder, which has the effect of destabilizing their equilibrium. The longitudinal acceleration, in a direction parallel to the axis Δ of the separator, as shown in FIG. 7b, has the effect of then separating the discrete elements Ed or fish in the longitudinal direction, which then makes it possible to ensure their counting , as described above in the description, using the counting means 4, which are not shown in detail in the drawing.

It will be noted that the outlet nozzle 2003 reduces the outlet orifice, in order to increase the speed of outlet of the water and to eject, more effectively, each of the separated fish.

Thus, the 2020 variable pitch helicopter plays a dual role, that of a pump which draws water towards the outlet and that of a separator, which, as each discrete element approaches the outlet, an increasing acceleration of the rotating wave of the fluid. As shown in a nonlimiting manner in FIG. 7a, an injection of additional water or fluid 2007 can be provided at the inlet of the separating cylinder 200 to increase the flow in the direction of normal flow in the separator cylinder. The drive means 2004 can advantageously be constituted by a drive motor 20044, a drive pulley or a battery of drive pulleys 20043, a drive belt 20042 and a pulley 20041 secured to the separator cylinder 2002 Of course, in place of the pulley battery 20043, a motor, fitted with a variable speed drive, can be used.

Of course, the separator cylinder 200 is mounted on a frame 201, which ensures good maintenance in position of the assembly constituted by the separator cylinder 200 and the drive means 2004. The frame 201 can be made mobile. In Figure 8, there is also shown an advantageous embodiment of an installation for counting larger fish. In the above-mentioned figure, a separator 200 denoted S I, S2, S3 in FIG. S is connected at the output of a sorter T of the discrete elements Ed on criterion of dimension or mass. The sorter T can advantageously consist of a sorter normally available on the market comprising a series of mobile rollers in rotation forming a sorting grid of different size and pitch according to the size of the fish to be sorted. By way of nonlimiting example, the sorter used for the tests was an alpha sorter sold by the company GIOVANNI MILANESE.

Of course, as shown in Figure 8, the discrete elements Ed are routed to each separation cylinder SI, S2, 53 according to a size criterion and, consequently, the drive speed in rotation of each separation cylinder can be modulated according to the size of the discrete elements to be separated.

In the tests carried out, the discrete elements to be separated were fish, such as trout, the sorting criteria having consisted in defining a first range of fish of mass less than 30 g, a second range of fish of mass between 30 g and 50 g and a third range of fish with a mass of between 50 g and 80 g. A device for counting discrete elements in suspension in a fluid medium has thus been described, which is particularly efficient because of the fact that this type of device allows precise counting of colonies of very large discrete elements, such as colonies of fry. presenting several million fry in a fish farming basin. This type of device is particularly suitable for integration into fish farming installations and has the great advantage of requiring practically no maintenance insofar as the whirling flow of at least part of the fluid Mf is carried out thanks to a natural phenomenon in the absence of the use of motor elements with a rotating part.

It will also be understood that the fishponds being equipped with the device which is the subject of the invention, these can of course, apart from using the device which is the subject of the invention, for counting the fry, continue to ensure their function of breeding pond.

Claims

1. Device for counting discrete elements (Ed) suspended in a fluid medium (Mf), characterized in that it comprises:

- a buffer tank (1) of said fluid in which said discrete elements (Ed) are suspended,

- means (2) for vortexing a portion of said fluid contained in said buffer tank,

- means (3) for forming a fluid flow vein connected to said means (2) for vortex flow, said means for vortex flow (2) and said means (3) for forming a fluid flow vein allowing, from any colony of elements in suspension, the ordering of each element (Ed) following a successive file of unique elements in said fluid flow vein, - means (4) for counting each element arranged in the vicinity of said fluid flow vein.

2. Device according to claim 1, characterized in that said means (2) for putting into swirling flow a portion of the fluid contained in said buffer tank comprise at least one funnel (20) of conical type.

3. Device according to claim 1, characterized in that said means for putting into vortex flow a portion of the fluid contained in said buffer tank are constituted by at least one funnel of the paraboloid or hyperboioid type.

4. Device according to one of claims 2 or 3, characterized in that said means for forming a fluid flow vein connected to said means for creating swirling flow are constituted by a nozzle or tube opening at the level of the narrowest part of the funnel, said tube or nozzle having at least one part transparent to electromagnetic waves.

5. Device according to one of claims 1, 2 to 4, characterized in that said swirling flow means are constituted by at least one funnel whose widest opening ^opens directly to the bottom of said buffer tank, said funnels being arranged vertically to subject said fluid portion of the buffer tank to Coriolis acceleration and create a swirling flow.

6. Device according to claim 5, characterized in that it includes several funnels in parallel and or in cascade.

7. Device according to one of claims 4 to 6, characterized in that said tube or nozzle having at least one transparent part is constituted by a tube transparent to visible light.

8. Device according to one of claims 5 and 7, characterized in that said means for counting each element arranged in the vicinity of said flow vein comprise:

- means for emitting electromagnetic radiation of a determined wavelength,

- means for focusing said radiation on the transparent part of said electromagnetic radiation of said nozzle or tube, - means of receiving said electromagnetic radiation transmitted by said transparent part of said tube or nozzle seat of the flow vein,

- means for counting the variation in intensity of the electromagnetic radiation transmitted during passage through the flow path of a suspended element.

9. Device according to claim 8, characterized in that said means for emitting electromagnetic radiation consist of a light-emitting diode.

10. Device according to one of claims 8 or 9, characterized in that the means for receiving said electromagnetic radiation consist of a photodiode or a phototransistor.

1 1. Device according to one of claims 8 to 10, characterized in that the means for emitting and receiving electromagnetic radiation, and the transparent zone of the tube or nozzle are enclosed in an opaque enclosure.

12. device according to one of claims 8 to 1 1, characterized in that said means for counting the variation in intensity of the electromagnetic radiation comprise:

- amplifier means connected at the output of the means for receiving the electromagnetic radiation delivering an amplified signal, - a threshold trigger circuit receiving the amplified signal delivered by said amplifier means and making it possible to generate, for a greater variation in amplitude of the amplified signal at said value, a trigger signal,

- a fast monostable circuit receiving the trigger signal and making it possible to generate a calibrated counting pulse, for each suspended element,

- a counting circuit itself receiving said counting pulses and making it possible to store the number of suspended elements counted.

13. Device according to one of claims 1 to 12, characterized in that in the case where said elements suspended in the liquid are living organisms, such as fry, said buffer tank, in its part opposite to said means of placing in vortex flow of a part of said fluid, comprises ultrasonic transducer means intended to cause the migration of said elements towards said means for setting vortex flow.

14. Device according to claim 13, characterized in that said transducer emits ultrasonic waves in pulsed mode.

1. Device according to claim 12, characterized in that in the vicinity of the means for creating a swirling flow of a part of the fluid are arranged electric field generating means, said electric field having a current density sufficient to cause temporary inhibition of the motor reactions of said living organism so as to prevent it from moving against the current.

16. Device according to one of claims 2 to 15, characterized in that funnels and tubes or nozzles of different caliber are provided, the opening of each funnel opening at the level of the buffer tank being provided with a calibrated sieve.

17. Device according to one of claims 2 to 16, characterized in that the internal wall of said funnels is provided with helical ribs in order to promote the swirling flow of said liquid.

1 8. Device according to claims 1 or 13, characterized in that said means (2) for putting into swirling flow a part of the fluid contained in the buffer tank comprise on a separator cylinder (200) said separator cylinder allowing a setting swirling flow with increasing acceleration of the fluid coming from the buffer tank and comprising the discrete elements (Ed) in suspension.

19. Device according to claim 18, characterized in that said separator cylinder (200) comprises: - an inlet connection nozzle (2001),

- a revolution enclosure (2002) provided on its internal wall with a variable pitch helicoid (2020),

- an outlet connection nozzle (2003), the inlet connection nozzle (2001), the outlet connection nozzle (2003) and the revolution enclosure (2002) being mounted in a sealed manner, and the enclosure of revolution (2002) being mounted to rotate around its longitudinal axis of symmetry (Δ) •»

- means (2004) for driving said enclosure of revolution in rotation, so as to subject said fluid coming from the constant reservoir to a swirling flow causing an increasing axial acceleration of the fluid to cause an axial separation of the discrete elements (Ed) in the direction of axial flow of the fluid.

20. Device according to claim 18 or 19, characterized in that a separator cylinder (200) is connected at the output of a sorter (T) of discrete elements based on dimension or mass criteria.