FR2484866A1 - Regulator for liquid amplitude control in swabbing tank - uses programmed calculator to control butterfly type air valve from separation level detector - Google Patents

Abstract

A level detector (14) is positioned to sense the separation level of two layers of the bed (12) above a grill (11). The products are separated by pulsing two superimposed layers. The high density products are evacuated through a pipe (13) in the base while the lighter products are evacuated by the overflowing water. A calculator (16) with a programmed memory (15) controls the opening and closing of a butterfly valve (6) to control the compressed air flow as pulses to the water in the tank. The pulse widths depend on the probe output and the program. The butterfly valve is periodically actuated to control the opening in the passage formed by a pipe (8) between the air chamber (3) and a release chamber (7).

Description

 The present invention relates to the separation by densimetric classification in liquid medium of grain products of different densities in a piston-type container or the liquid is subjected to pulsations pneumatically controlled by admission of compressed air into a chamber communicating with the separation chamber, the bottom consists of a grid immersed in the liquid. In the bed above the grid, the products to be classified are separated into two superimposed layers, a lower layer composed mainly of high density products, and an upper layer composed of low density products. It then becomes easy to discharge the products of the two aforementioned layers separately.

 The invention relates more particularly to the regulation of the amplitude of the pulsation in a pneumatic piston plunger of this kind.

 Such regulation is essential to properly evacuate heavy products depending on the quantity of said products to be evacuated. It is then advisable to increase the amplitude of the pulsation when the quantity of heavy products to be evacuated increases, causing the level of separation of the layers to rise, and to decrease the amplitude of the pulsation otherwise.

A known solution consists in using a probe able to detect the level of separation of the two layers of products and to cosmander the degree of throttling of an air leakage member.

 This solution has the drawback of giving rise to a permanent leak, of variable instantaneous flow, throughout the duration of the admission of the compressed air.

The tank then operates in poor conditions since the shock effect resulting from the rapid opening of the compressed air intake member is considerably attenuated.

 Another known solution consists in controlling, from the aforementioned probe, the degree of opening of the compressed air intake member.

 The drawback previously mentioned is not eliminated, however, since the shock effect, depending on the degree of opening of the intake member, is variable and can, in certain cases, become weak.

 The main object of the invention is to avoid the drawbacks inherent in known containers.

 It essentially consists, in order to fully benefit from the shock effect, to effect the regulation of the amplitude of the pulsation by acting on the duration of admission of the compressed air, the control of the admission member being , for this purpose, slaved to a sensor for detecting the level of separation of the layers.

A more specific subject of the invention is a method for regulating the amplitude of the pulsation in a pneumatic tonnage tank in which products to be classified are separated into two superimposed layers, characterized in that, on the one hand, it detects the level of separation of the layers by means of a probe emitting a measurement signal, and that, on the other hand, the opening and closing of the air admission member in the tank is sequentially controlled , the duration of the opening phase being determined by the signal emitted by the probe, said signal being directed to a computing unit which receives information emitted by a unit for storing the opening and closing program of the '' intake member and which delivers a control signal from said intake member,
In a particularly advantageous manner, the program for opening and closing the air exhaust member outside the tank is stored in memory, preferably in the same unit, the calculation unit receiving information representative of this program and delivering a signal of co-ande of said exhaust member.

 The subject of the invention is also a pneumatic piston tray for implementing the method, comprising a pulsation chamber filled with liquid, said pulsation chamber communicating with a separation chamber, the bottom of which is constituted by a grid immersed in the liquid, an air chamber in relation to the pulsation chamber, a member for admitting compressed air into said air chamber, and a member for exhausting air from said air chamber, characterized in that it further comprises a probe capable of detecting the level of separation of the layers and of transmitting a measurement signal a unit for storing the program for opening and closing of the compressed air intake member which delivers information representative of said program, and a calculating unit which receives the information delivered by the storage unit and the signal emitted by the probe, and which delivers a command signal from the admission member.

 The storage unit also contains the program for opening and closing the exhaust system, and the calculating unit is designed to receive information representative of this program and to deliver a control command signal. the exhaust member.

The intake and exhaust members are advantageously constituted by valves, preferably butterfly valves.

The invention will be better understood by referring to the description which follows, made with reference to the appended drawings, relating to a particular embodiment given by way of nonlimiting example.

 Figure 1 shows, in cross section, a pneumatic piston container according to the invention.

Figure 2 is a diagram illustrating the operation of this tank.

 In FIG. 1, the reference numeral 1 designates the pulsation chamber of the pneumatic piston plunger for the separation of grain products of different densities. Chamber 1 is supplied with water by a tube 2. Inside chamber 1, the water is subjected to pulsations pneumatically controlled by admission of compressed air. To this end, an air chamber 3 is fitted through the chamber 1. Said air chamber, open over its entire length at its lower part, is thus placed in communication with the pulsation chamber 1.

The supply of compressed air to the chamber 3 is ensured, from a manifold 4, by means of a series pipe 5 on the laguelle is mounted an intake member, such as a butterfly valve 6. Said butterfly valve is controlled to cyclically ensure the opening and closing of the passage established by the pipe 5 between the feeder 4 and the air chamber 3. The exhaust of air from the chamber 3 is ensured, to a pot of expansion valve 7, by means of a pipe 8 on which is mounted an exhaust member, such as a butterfly valve 9. Said butterfly valve is controlled to cyclically open and close the passage established by the pipe 8 between the air chamber 3 and the expansion pot 7.

 The pulsations are transmitted to the water contained in a separation chamber 10 situated above the pulsation chamber 1, said chambers communicating with each other. The bottom of the chamber 10 is constituted by a grid 11 in the form of a perforated table, which is immersed in water. In the bed 12 located above the grid 11, the products are separated under the effect of pulsations, in two superimposed layers. The products of the lower layer, of high density, are evacuated by the tube 13 which is provided at the lower part of the chamber 1, while the products of the upper layer, of low density, are evacuated with water, by overflow thereof outside the chamber 10.

The foregoing description relates to provisions relating to a known plunger tank. We will now describe the characteristic arrangements of the invention, namely the means for regulating the amplitude of the pulsation.

 The reference numeral 14 designates a probe capable of detecting the level of separation of the two layers of the bed 12 and of transmitting a measurement signal representative of said level.

 Reference numeral 15 designates a unit for storing the program for opening and closing the butterfly valve 6. Said unit delivers, in the form of a signal, information representative of said program.

The signals delivered by the probe 14 and by the unit 15 are sent to a computing unit 16, which delivers a control signal from the butterfly valve 6.

The units 15 and 16 are provided so that the duration of the opening of the butterfly valve 6 is controlled by the signal emitted by the probe 14.

 In a particularly advantageous manner, the program for opening and closing the butterfly valve 9 is also stored in the unit 15. The unit 16 then delivers a control signal from the butterfly valve 9, and said unit is provided so that the opening time of the butterfly valve 9 is also controlled by the value of the signal emitted by the probe 14.

 This latter arrangement makes it possible, in a particularly simple manner, to avoid any air deficit which would occur in the event that the quantity of air in the exhaust is greater than the quantity of compressed air admitted. The control of the butterfly valve 9 by the signal delivered by the unit 16 then makes it possible to adapt the duration of opening of said butterfly valve to the exhaust of a quantity of air suitably predetermined.

 FIG. 2 illustrates, in the form of a diagram, the opening and closing cycles of the intake and exhaust members. The upper line (CA) corresponds to the operation of the butterfly valve 6, while the lower line (CE) corresponds to the operation of the butterfly valve 9. The set of two lines corresponds to a single piston cycle. The openings of said butterfly valves are, of course, spaced over time.

Each solid line plot corresponds to a theoretical cycle as provided for by the stored program. Each plot in broken lines illustrates the correction made to the theoretical cycle under the action of the signal emitted by the probe 14.

 According to the notations adopted, the theoretical duration of full opening of the butterfly valve 6 is reduced from (t2 - tl) to (t'2 - tl) while the duration of full opening of the butterfly valve 9 is reduced by (t4 - t3 ) to (t'4 - t3).

 It goes without saying that these durations could on the contrary be increased compared to the theoretical durations, according to the indications of the probe 14. The instants t'2 and t'4 then being respectively after instants t2 and t4.

It was also admitted that the duration corrections were made respectively at the end of admission and at the end of exhaust. It would, of course, be possible to make these corrections at the start of intake and in exhaust exhaust, the butterfly valves ó and 9 then receiving their opening control signal at an instant offset in time with respect to the 'moment theoretically foreseen by their respective programs.

 It goes without saying that it is possible to divide the tank longitudinally into a plurality of cells. Each cell is then provided in accordance with the above description.

In any case, the duration of opening of the butterfly valve 6 is controlled so that the pulsation decreases in intensity when the quantity of heavy products decreases, or more precisely falls below a set value.

 Although the invention has been described with reference to a particular embodiment, it goes without saying that it is in no way limited thereto and that modifications can be made to it without departing from its field.

We can, of course, replace any of the means described by a technically equivalent means.

 The invention therefore covers, in addition to the example shown, its various alternative embodiments.

Claims (5)

1. Method for regulating the amplitude of the pulsation in a pneumatic tonnage tank where products to be classified are separated into two superimposed layers, characterized in that, on the one hand, the level of separation of the layers is detected at by means of a probe (14) transmitting a measurement signal, and in that, on the other hand, the opening and closing of the member (6) for admitting air into the tank is controlled sequentially, the duration of the opening phase being determined by the signal emitted by the probe (14), said signal being directed to a computing unit (16) which receives information emitted by a program storage unit (15) opening and closing the intake member (6) and which delivers a control signal from said intake member. 2. Method according to claim 1, characterized by storing the program for opening and closing the member (9) for exhausting air from the tank, the calculation unit (16) receiving information representative of this program and delivering a control signal from said exhaust member. 3. Pneumatic piston tub for implementing the method according to one of claims 1 or 2, comprising a pulsation chamber (1) filled with liquid, said pulsation chamber communicating with a separation chamber (10), the bottom consists of a grid (11) immersed in the liquid, an air chamber (3) in relation to the pulsation chamber (1), a member (6) for admitting compressed air into said air chamber, and a member (9) for exhausting air from said air chamber, characterized in that it further comprises a probe (14) capable of detecting the level of separation of the layers and of transmitting a signal measurement, a unit for storing the memory (they) of the program for opening and closing the member (6) of compressed air intake which delivers information representative of said program, and a calculation unit (16) which receives the information delivered by the storage unit (15) and the signal emitted by the probe (14) and which delivers a control signal from the intake member (6). 4. Pneumatic piston tray according to claim 3, characterized in that the memory unit (15) contains, in addition1 the program for opening and closing of the exhaust organ (9) air, and in that the calculating unit (16) is arranged to receive information representative of this program and to deliver a control signal from the exhaust member (9). 5. Tray pneumatic piston according to claim 2, characterized in that the intake member (6) and the exhaust member (9) are constituted by butterfly valves.