DE2342475B2 - Method for the automatic control of a self-draining sludge centrifuge and sludge centrifuge for carrying out this method - Google Patents

Description

The invention relates to a method for the automatic control of a self-emptying sludge centrifuge according to the preamble of the main claim and a sludge centrifuge to carry out the Procedure.

A method for the automatic control of the separation by means of self-draining is known Separators for a liquid with intermittent discharge of the sediment, the following steps contains: supply of the starting liquid in the separator drum, its separation, discharge of the separated Liquid depending on the separated amount, continuous liquid withdrawal from the sludge chamber of the Separator drum, determination of the characteristics of the removed liquid, including its electrophysical Data. After determining the electrophysical characteristics, a command is issued for Discharge of the sediment from the drum 1 as soon as the fraction to be removed (e.g. water) the has reached the specified level in the sludge chamber. Thereupon the fraction to be removed carried out.

To carry out the method described, a device is used, which is a separator drum contains, on the basis of which a vertically movable annular piston is arranged, which is equipped with a drive is provided for its adjustment when discharging the sediment. Said facility includes a Connection for discharging the separated liquid from the drum and a device for removal the liquid from the sludge chamber, which is fed to a transmitter for electrophysical characteristics will.

The device for carrying out the known method works as follows. In the separator drum the starting liquid is introduced. This is where the separation process begins. In the initial period During the separation process, the separated liquid is sent to the transmitter for electrophysical characteristics. In the course of the separation, as soon as there is a certain amount of soil salt in the sludge chamber and the fraction to be removed has accumulated, the latter begins to donate electrophysical To get identification data. Since the value of an electrophysical characteristic of the fraction in is known in advance, the encoder set to this value issues a when this value is reached Command to the control system of the piston drive to discharge the sediment and to discharge the fraction to be removed. As a result, the separator is emptied. The duty cycle continues of the separator is repeated in the same way.

Nevertheless, the known method and the known device for separating milk cannot are used whose component fractions do not have any previously known electrophysical Have characteristics and where there is no sharp boundary between the individual fractions, if they are in the sludge chamber and the sediment is not homogeneous.

This device contains only one transmitter for the electrophysical characteristic value and only one device for supplying the liquid to be taken from the sludge chamber to this transmitter. But since the electrophysical characteristics of the liquid to be removed from the sludge chamber of the drum when separating milk not only from the level of sediment, but also from other factors depend on which ones are impossible to take into account, the donor decides with this facility equipped, has no precise information about the level of the sediment. The working cycle of the Establishment is then not determined by the level of the sediment but by some secondary factors regulated. It is inevitable that the separated liquid together with the sediment is ejected, or the sediment gets into the Tellcrpaket of the drum, whereby an imbalance of the Drum is caused.

For a successful control of the separation process

In the course of the process mentioned, the batch to be separated must necessarily meet the following basic requirements correspond to: the component fractions must electrophysical: · kaiische characteristics known in advance to have; the electrophysics?! - must see characteristics of these fractions throughout the The separation process remain stable; there must be a sharp boundary between the individual factions be recognizable as long as they are in the mud chamber; the sediment must be homogeneous. ι ο

However, milk as a separating substance does not meet any of the requirements mentioned. Above all is the milk sediment not homogeneous. Although it is close to the drum circumference, it is in most of the mud chamber a liquid whose physical and mechanical properties differ little from those of milk differentiate. As a result, there is no clear dividing line between the milk and the sediment. The sludge chamber is filled with a mixture of milk and liquid sediment, with the physico-chemical and electrophysical characteristics of this liquid are related to both Change the drum radius as well as the time.

Since the liquid in the sludge chamber is not a pure sediment, but an addition to milk its electrophysical characteristics are determined by the characteristics of these two components certainly. As is known, the electrophysical characteristics of milk are not constant and depend on many factors. So z. B. when storing the milk in containers, their acidity, which reduces their electrical conductivity and dielectric constant change accordingly. As long as the milk is in the Separator drum is located, you can determine a so-called homogenization effect, which is causes a change in the electrophysical characteristics, with their degree of change from the mean Depends on the diameter of the fat globules of the starting milk; this parameter is also volatile.

Consequently, with the same sediment level, completely different values of the electrophysical Characteristic data of the liquid removed from the sludge chamber correspond, these values in principle are not predictable. It follows that when controlling the milk separation according to the above Procedure the separation sequence is disturbed. In other words: the emptying de ;, separator is before or take place after the required time. In the former case, this causes the separated substance to be ejected from the drum; in the second case, the sediment gets into the plate pack, causing an imbalance in the drum is caused.

Also known is an applied in the dairy industry method for automatically controlling the milk separation with self-cleaning separators for ^{r> r>} a liquid with intermittent discharge of the sediment, after which the Ausgangsflü ^c ing into the separator is introduced, separated and the separated liquid is derived. During the separation process, a command for emptying is programmed in after a certain period of time, after which the sediment is discharged.

The device for carrying out this process contains a separator drum, on the basis of which a ί ^γ > annular piston for discharging the sediment is arranged and equipped with a drive, also a connection for discharging the separated liquid and a time relay that is electrically connected to the piston drive

The facility works as follows. The starting liquid is introduced into the drum where their separation occurs. The separated material is discharged through the exhaust connection. According to certain The timing relay issues time segments in accordance with the specified program! Commando to unsubscribe of the sediment from the drum. Now the sediment is discharged, after which the work cycle repeated.

The above-mentioned method and the device provided for it are not very effective for separating milk. Since such properties of milk as its impurity, acidity and other characteristics are always inconsistent it is impossible to predict the level of sediment that will be present during the programmed Time interval between two consecutive evacuations. Since the duration of the event is not made dependent on the actual sediment level, either an incomplete one is always carried out Discharge of the sediment or an ejection of the separated liquid together with the sediment.

Also known is a method for the automatic control of the separation with centrifugal separators for a liquid with intermittent discharge of the sediment, in which a measurement of the light transmission the initial and clarified liquid (fugate) is provided. Depending on the amount of in the course the separation of the accumulated sediment, the latter reaches the edge of the plate stack, begins in this to penetrate and, being carried away by the flow of the incoming liquid, is gradually out of the with it Separator drum derived together with the separated product. The degree of clarification becomes strong reduced. A command to empty the separator is given as soon as the difference in Light resistances of the starting liquid and the fugate becomes zero.

The device for carrying out this process contains a separator drum, on the basis of which a Ring piston is arranged for discharging the sediment and is equipped with a drive, furthermore a Discharge connection, a clear cuvette with a sample of the source liquid, a clear one Cuvette through which the clarified liquid, which is connected to the discharge connection, flows electronic bridge with two photo resistors and two ohmic resistors, a light prism wedge for balancing the bridge and a lighting lamp for the bridge photoresistors.

The facility works as follows. The raw material is fed into the separator drum, separated and finally diverted through the discharge connection. The light from the lighting lamp falls on the photoresistors, after having previously placed the transparent cuvette with the starting liquid and happened to Fugat. The light resistances of the fugat and the starting material are different, consequently, the electrical resistance values of the photoresistors are also different because of their illuminance is different. The electronic bridge is created by pivoting the prism wedge by one adjusted to a certain angle. As soon as the sediment gets into the package the conical plate will be the light resistances of the starting product and the fugat are equal to each other, the bridge is detuned, after which a sienal to discharge the sediment

the separator drum follows. The separator is then emptied. After emptying the separator the facility's cycle of operation is repeated.

The mentioned method for the automatic control of the separation process as well as the facility to -, however, its implementation cannot be used to separate milk. First, the contains sediment obtained in the milk separation process contains a large number of pathogenic microbes that result from the Milk was excreted. Moreover, when working according to the above method, it is inevitable that the Sediment gets into the separated liquid, which is not allowed according to the health regulations. Secondly the mentioned method and the corresponding one are suitable Device only for separating transparent liquids, which milk does not belong to.

It is also a device for controlling the workflow of centrifuges, especially the Filling process in the centrifugal drum by electrically influencing the control unit for the work process known depending on the degree of drum filling (see DE-PS 11 44 198), which is designed in such a way that the influence of the control element by the compensating current of a measuring bridge to determine the Thermal conductivity of two separated substances takes place, of which one measuring resistor each one which is assigned to the components of the material to be centrifuged separated by the centrifugal force, the Device can be designed so that at least two measuring resistors in the drum front wall are arranged, of which two measuring resistors can be connected to the measuring bridge by means of lines.

In this known device, the operation is based on the fact that the difference as physical The parameter of the components obtained during centrifugation is the thermal conductivity. Such a one known arrangement, however, has the disadvantage that it is for uninterrupted monitoring and Determination of the fill level of the sediment in the sludge chamber of the drum of the milk separator and for emitting a signal for discharging when it reaches a predetermined filling level cannot be used because the characteristic data to be measured relating to the thermal conductivity of the Liquid measured variable are not constant, as a large part of the sediment consists of liquid separator sludge which differs little from milk in terms of its physical properties.

The purpose of the invention is to remedy these mentioned shortcomings. The invention lies therefore the object of the invention is a method and a device for the automatic control of the separation of milk and the intermittent discharge of the sediment to create an emptying of the Separator drum guaranteed without significant loss of separated liquid and at the same time prevents the sediment from getting into the plate pack

The object is achieved by the characterizing features of claim 1

A sludge centrifuge according to claim 2 is used to carry out this process.

It is advantageous if an electromagnetic relay is used as the threshold element and between the comparison device and the threshold element an amplifier with an adjustable gain factor is provided

The influence of secondary factors, e.g. B. a change in the characteristics of the output liquid wedge to be tested on the work cycle of the facility is excluded. The threshold element continuously receives one precise information on the sediment level and issue a command to discharge as soon as the specified Value is reached. This prevents the separated substance from being shared with the sediment is discharged and the sediment gets into the plate pack. This increases the effectiveness of the separation process and unbalances the drum prevented.

Since the gain of the arranged between the comparison circuit and the threshold element Amplifier can be regulated, if necessary, by changing the gain factor accordingly of the amplifier, the predetermined sediment level in the sludge chamber can be regulated or changed without turning off the separator. Such a need can arise, for example, if the Sediment attaches to the drum wall.

On the basis of the embodiment shown in the drawing, the invention is sewn in the following explained. The drawing shows the longitudinal section of a device for carrying out the inventive device Process consisting of a self-cleaning separator for a liquid with intermittent discharge of the sediment and is equipped with a drive that is regulated by a control system will.

The self-cleaning sludge centrifuge contains a separator drum 1 with a bottom 2 on which a vertically movable annular piston 3 is arranged for the intermittent discharge of the sediment.

The upper part of the drum 1 represents a conical cover 4. On the drum base 2 a plate holder 5 is arranged on which a packet of conical plates 6 is mounted, which are used to separate the Liquid flow in individual layers are determined In the upper part of the conical plate 6 is a separation plate

7 is provided for separating the liquid to be separated from the liquid derived from the sludge chamber Liquid is used. There are slots in the drum base

8 for discharging the sediment from the drum 1 and openings 9 for the supply of buffer liquid provided in the space between the drum base 2 and the annular piston 3.

The discharge connection begins in the upper part of the separator drum 1, and that outside the separator ends and serves to discharge the separated liquid from the drum. The main parts of the discharge connection are: a peeling disk 10 for generating pressure in the discharge connection as well as a with their Working space connected channel 11, which is intended for draining the separated liquid with the channel 11 is connected to a channel 12 which is intended for taking samples of the separated liquid Im Channel 12, a throttle device 13 is arranged. The channel 12 and the throttle device 13 are not absolutely necessary according to the invention. They depict elements of a possible structural design the invention.

In the device is a device for removing liquid from the sludge chamber of the drum 1 provided, which contains a removal tube 14 on the outside of the surface line of the conical part of the separating plate 7 is arranged as well as a rubber ring 15. which the mud chamber of the drum from the space between the conical cover 4 and the separating plate 7 separates,

whereby the liquid can be extracted from the sludge chamber from a precisely defined zone. The apparatus for removal of liquid also contains a paring disc 16, which the * mer withdrawn liquid from the area of the separator serves to generate pressure in the duct 17 for discharging from the Schlammkam-. In order to avoid losses of the separated liquid, the channel 17 is connected to the inlet pipe 18, through which the liquid to be separated is fed into the separator drum 1. The channel 17 ι ο is connected to a channel 19 in which a throttle device 20 identical to the throttle device 13 is arranged. The channel 19 and the throttle device 20 are not absolutely necessary. They are elements of a possible further development of the device according to the invention.

In order to be able to move the annular piston 3 in the vertical direction, it is provided with a drive. This contains a container 21 with a buffer liquid, which can be replaced by the water supply network, a pressure reducer 22, which is used to reduce the pressure in the channel 23, which the container 21 through a pipe 24 and the opening 9 in the drum base 2 with the cavity between the drum base and the Ring piston 3 connects. The channel 23 and the pressure reducer 22 are only used for maintenance the working pressure in the cavity between the drum base 2 and the annular piston 3. For emptying the separator drum 1, however, a channel 25 is used, which also the container 21 with the jo The cavity between the drum base 2 and the annular piston 3 connects. In the drum base 2 is a Valve 26 arranged for discharging the buffer liquid from the drum 1 during emptying.

The device according to the invention contains an anjs Drive control system that controls the separation process depending on the sediment level in the sludge chamber. The control system contains a transmitter 27 for electrophysical characteristics of the separated liquid as well as a transmitter 28 for electrophysical characteristics of the values taken from the sludge chamber Liquid The transmitters 27 and 28 are electrical in adjacent branches of a Wheatestone bridge turned on, which in the given embodiment of the device an electrical comparison circuit for which represents the signals The Wheatestone Bridge, which contains equal ohmic resistors 29 and 30 connected via an amplifier 31 to a threshold element 32, the output signal of which is one in the channel 25 arranged, electromagnetic valve 33 and a timing relay 34 is supplied to the electromagnetic valve 33 is electrically connected

The transmitters 27 and 28 are arranged in the channels 12 and 19, respectively, with the throttle devices 13 and 20 generate equal pressures of the liquid in these channels, which is fed to the sensors with the Throttle devices 13 and 20 connected channels 12 and 19 consist of structural units, the conical Rotameters or measuring tubes are similar. This is why the liquid that has passed through these structural units reverses back into channel 11 or 17. The transmitters 27 and 28 can also be placed directly in the channel 11 and 17, respectively be accommodated. In the device according to the invention, transmitters for electrophysical Characteristics of two types are used, namely conductometric and capacitive.

The amplifier 31 is equipped with a gain controller. The threshold element 32 consists of given embodiment from an electromagnetic relay. But you can also do this with others Types of threshold elements, e.g. B. use a threshold trigger. The Wheatestone Bridge forms a special case of a comparison circuit for the signals. It can also be any other, for this one Purpose-suitable variant of a comparison circuit can be used.

The device for carrying out the method according to the invention works as follows. In the rotating separator drum 1 is through the pipe 35 and the inlet pipe 18, the starting liquid, if necessary milk, introduced. From the tube 18 comes the M.Ich on the interior of the plate holder 5 first into the sludge chamber, which is passed through the conical cover 4 and the annular piston 3 is formed, and then in the package of the conical plate 6.

From the beginning of the work of the separator until it is emptied, the annular piston 3 is in its upper position, in which he keeps the emptying slots closed. The annular piston 3 is through the Buffer liquid is held in the upper position, from the beginning of the separation uninterrupted from the container 21 is fed into the drum 1 via the pressure reducer 22, the channel 23 and the pipe 24.

During the supply of the milk, it is separated in the package of the conical plates 6. The separated liquid which is fed through the channel 11 with the aid of the paring disc 10 is used for further processing from the Drum derived. The sediment obtained in the course of the separation process collects in the Sludge chamber at the edge of drum 1. Simultaneously with the separation, and that during the entire separation, part of the liquid is removed from the sludge chamber with the help of the paring disc 16 through the extraction pipe 14, through the channels 17 and 19 and the throttle device 20 continuously to the Sensor supplied A part of the separated liquid is fed through the channels 11, 12 and the throttle device 13 also fed continuously to the encoder 27 during the entire separation, that is to say simultaneously with the supply of the liquid withdrawn from the sludge chamber to the transmitter 28.

The transmitters 28 and 27 determine one of the electrophysical characteristic values from the sludge chamber withdrawn or separated liquid For milk this can be the specific electrical Conductivity or the dielectric constant.

The following is used as the electrophysical control value the specific electrical conductivity assumed. In this case, the sensors 27 and 28 work conductometric. In the initial period of separation, the specific electrical conductivity is the den The liquid supplied to the sensors is the same as the separated liquid and the liquid coming from the sludge chamber, because only milk is supplied to both donors. As a result, the Wheatestone Bridge is leveled and their output signal is zero.

As the separation progresses, the specific electrical conductivity of the separated liquid and gives way of the liquid withdrawn from the sludge chamber decreases more and more from the original value. the electrical conductivity of the separated liquid changes, as mentioned, as a result of a change in the electrical conductivity of the starting liquid, for example due to an increase in its acidity Change in the electrical conductivity of the liquid withdrawn from the sludge chamber is

probably due to the change in the electrical conductivity of the starting liquid as well as due to the accumulation caused by the sediment. The liquid withdrawn from the sludge chamber contains as it progresses Separation of less and less fat and more and more protein, thereby increasing their electrical conductivity changes accordingly. Consequently, the difference between the electrical conductivity of the separated and the liquid withdrawn from the sludge chamber by changing the latter determined, which is caused by a corresponding accumulation of the sediment.

The transmitters 27 and 28 record the values of the electrical conductivity of the liquids supplied to them by changing their electrical resistances accordingly. This change causes a Detuning the Wheatestone Bridge. As the donors in neighboring branches of Wheatestone If a bridge is connected, the electrical signal at its output is proportional to the difference in resistance the sensors 27 and 28 and thus proportional to the sediment level in the sludge chamber of the drum 1. The Wheatestone Bridge output grows proportionally as the sediment level increases and is continuously fed via the amplifier 31 to the input of the threshold element 32, which consists of an electromagnetic relay.

According to the method according to the invention, the limit level of the floor level is determined by the response threshold of the electromagnetic relay. The limit level of the sediment can thereby through corresponding change in the amplification factor of the amplifier can be controlled, since the input signal of the electromagnetic relay from both the Wheatestone Bridge output and the The amplification factor of the amplifier depends by reducing or increasing the amplification factor With the help of the controller, the predetermined limit level of the sediment can be compared to the pivot point or the circumference of the drum can be adjusted.

As soon as the sediment has reached the specified level, the input signal reaches the electromagnetic Relay 32 its response threshold. The relay 32 responds to what a signal for emptying the Means separators. When the electromagnetic relay 32 responds, an electromagnetic Valve 33 is open and the buffer liquid comes out

in the container 21 through the channel 25 into the pipe 24, without passing through the pressure reducer 22. The pressure in the cavity between the drum base 2 and the The ring piston 3 of the drum now exceeds the working pressure. The through a channel 36 on the Pressure transmitted to the outer surface of a piston 37 of the valve 26 pushes the piston 37 inward, whereby the Cavity between the drum base 2 and the annular piston 3 of the drum 1 with the outer space connected. The buffer liquid is discharged from the drum 1, the annular piston 3 is lowered, whereby the emptying slots 8 are opened. Under the action of centrifugal forces, the Dregs discharged from the drum through the emptying slots. Simultaneously actuates the electromagnetic Relay 32, the timing relay 34, which controls the duration of the emptying process. The duration of the The emptying process is calculated in such a way that the sediment, the level of which is specified, is complete discharged and so the separated product cannot be ejected.

After the required duration of the emptying process has elapsed, the timing relay 34 gives a command to close the electromagnetic valve 33. The pressure of the buffer liquid in the drum 1 becomes equal to the working pressure, whereby the valve 26 is closed. The piston 3 is raised and thus closes the emptying slits 8. The discharge of the sediment is interrupted. The work cycle the establishment repeats itself anew.

1 sheet of drawings

Claims (3)

Patent claims: 1. Method for the automatic control of a self-emptying sludge centrifuge with intermittent discharge of the sediment, in which the starting liquid is introduced into the separator drum, separated and the separated liquid is discharged during the separation and in which the liquid is continuously removed from the Remove the sludge chamber from the separator drum men, electrophysical parameters of the withdrawn liquid are determined and subsequently a command to discharge the sediment from the separator drum is given is, characterized in that in the separation of milk simultaneously with the Removal of the liquid from the sludge chamber In addition, continuously a sample of the separated Liquid is withdrawn, its electrophysical characteristics are determined, whereupon the obtained electrophysical characteristics of the liquid withdrawn from the sludge chamber and the separated liquid can be compared with each other and as soon as the by comparing the electrophysical characteristics obtained difference has reached an amount that the specified Filling level of the sediment in the sludge chamber of the separator drum corresponds to a command is given to discharge the sediment from the separator drum. 2. Sludge centrifuge for performing the method according to claim 1 with an im Discharge channel of the heavy fraction arranged donors for determining the discharge slots controlling physical parameters which are in the is Liquid located in the sludge chamber of the separator drum, characterized in that additionally In the discharge channel (I)) of the light fraction, another transmitter (27) for measuring electrophysical Characteristic values are provided, with both transmitters (27, 28) in a comparison device (27, 30) are arranged with a signal for carrying out the discharge of the sediment Achieving a predetermined level of the same delivering threshold element (32) electrically connected is. 3. Sludge Centrifuge according to claim 1, characterized in that an electromagnetic relay (32) is used as the threshold element and is provided between the comparing means (29,30) and the v> threshold element, an amplifier (31) with adjustable amplification factor.