EP0342455A2 - Filter centrifuge for the separation of suspensions - Google Patents

Abstract

Filter centrifuges for the separation of suspensions, the drum of which has a corotating syphon device according to DPS 22 60 461, have the disadvantage that the filtration-accelerating action of the syphon device is destroyed by gas intrusions into the collecting space under the filter medium. Until now, this gas could only be expelled after each charge by backwashing through the filter medium once the solid had been removed. <??>The object consists in providing an outlet which permits the expulsion during filtration of gases which have penetrated the syphon space. <??>This object is achieved by means of a non-return valve (18) radially arranged within the syphon device, preferably on the drum floor and connected to the collecting space (11) or by an additional syphon device (17, 19, 20, 21) acting as non-return valve. <??>This device can be used on discontinuously operating filter centrifuges with rotation syphoning according to DPS 22 60 461, the housing inner space of which is at ambient pressure or is fed with compressed gas for the purpose of further accelerating the filtration. <IMAGE>

Description

The invention relates to a "filter centrifuge for separating suspensions according to the preamble of claim 1.

Rotating siphon devices are attached to the drums of filter centrifuges according to German Patent Specification 22 60 461, which flow through the filtrate separated from the suspension after it has passed the filter medium and a collecting space, with the exclusion of gas.

The filtrate gets into a ring cup attached to the outside of the drum and is made from it e.g. derived by means of a peeling pipe which can be swung in and out. The peeling tube is also used to adjust the liquid level in the ring cup. If this level is lowered into a region radially outside the filter medium, the siphon device causes a pressure drop under the filter medium, relative to the pressure in the centrifuge housing.

This increases the driving force that causes the filtration compared to conventional centrifuges by the pressure difference that exists between the surface of the filter cake and the collecting space, and the filtration is accelerated.

However, this pressure difference regresses when the filtrate liquid releases gaseous components into the collecting space under the filter medium or when gas passes through the filter medium.

With the device according to DPS 22 60 461, after each centrifuging batch, ie after the filter cake has been peeled out of the drum, gas which has penetrated into the collecting space can be displaced. For this purpose, liquid is poured into the ring cup of the siphon device and the peeling tube is pivoted out of the ring cup.

As a result, a pressure drop is formed from the outside against the filter medium and the gas which has penetrated is forced through the filter medium.

However, this displacement of gas is only possible after the filter cake has been removed except for a residual layer. If the filter cake is still in the drum, the resistance to gas removal through the filter cake is too great and the filtration would also be disturbed in this process step.

With the invention, a device is created which allows gas which has penetrated into the collecting space during a centrifuging batch to be rapidly displaced into the housing surrounding the drum.

According to the invention this is achieved in that gas discharge lines are preferably provided in the rear wall of the drum and are provided with a pressure-dependent outflow device.

The outflow device can consist of a valve which opens at a slight overpressure in the collecting space relative to the pressure prevailing in the centrifuge housing and closes at an opposite pressure drop, that is to say a greater pressure in the housing than in the collecting space. Another solution according to the invention is that the outflow device consists of a rotating siphon which is filled with liquid and is designed such that gas flows from the collecting space to the housing at a low pressure drop from the collecting space to the housing and gas closure at a greater pressure drop from the housing to the collecting space is guaranteed.

• Abb. 1 : Einen Schnitt durch eine Zentrifuge mit Rotationssiphon und einem Rückschlagventil zur Gasableitung aus dem Sammelraum.
• Abb. 2: Eine Zentrifugentrommel, bei der anstelle eines Rückschlag­ventils eine Siphoneinrichtung zur wechselseitigen Gasab­sperrung und -ableitung dient, im Betriebszustand der Gasab­sperrung.
• Abb. 3: Wie Abb. 2, jedoch im Betriebszustand der Gasableitung.
• Abb. 4: Zeigt einen Teilschnitt durch eine Zentrifugentrommel mit Rotationssiphon und einem Drucksensor im Filtrat-Sammelraum.

Exemplary embodiments are shown in the drawings. Show it:

• Fig. 1: A section through a centrifuge with a rotary siphon and a check valve for gas discharge from the collecting space.
• Fig. 2: A centrifuge drum, in which a siphon device is used instead of a check valve for mutual gas shutoff and discharge, in the operating state of the gas shutoff.
• Fig. 3: Like Fig. 2, but in the operating state of the gas discharge.
• Fig. 4: Shows a partial section through a centrifuge drum with a rotating siphon and a pressure sensor in the filtrate collecting chamber.

According to Fig. 1, the feed and discharge devices filling pipe (2), peeling knife (3), solids chute (4), pressure relief valve (5), backwash pipe (6) and filtrate peeling pipe (7) are attached to the housing (1).

The siphon drum (9) with the filter medium (10), the collecting space (11), the siphon disc (12) and the ring cup (13) is seated on the shaft (8). According to the figure, a filter cake (14) is deposited on the filter medium (10). The collecting space (11) is partially filled with filtrate liquid (15), which has a lower (radially larger) liquid level in the ring cup (13). There is at least one bore (17) and at least one check valve (18) in the rear wall of the drum (16).

According to Figs. 2 and 3, the horizontal branch (19) of the bore (17) is followed by a radially outwardly directed pipe (20) which is immersed in the siphon cup (21) when liquid flows through the refill pipe (22). was fed.

The operation of the device acc. Fig. 1 is as follows:
Before each batch of centrifugation, both the ring cup (13) and the collecting space (11) are almost completely filled with liquid through the backwash tube (6) with the filtrate peeling tube (7) swung out.

The centrifuge drum (9) is then charged with suspension via the filling tube (2). The filtrate peeling tube (7) swings into the ring cup (13) and lowers the liquid level in the ring cup (13) compared to the level in the collecting chamber (11). As a result, a low pressure arises under the filter medium (10) compared to the surrounding housing. The pressure difference is determined by the accelerated mass of the liquid column Δ h +. For example, with an acceleration of 1000 x 9.81 m / s² and water as the filtrate liquid, a Δ h + of 20 mm, a pressure difference of 2 bar. However, if an increasing gas cushion is formed in the collecting space (11) as a result of gas ingress through the filter cake or degassing of the filtrate, Δ h + and thus the additional pressure drop become smaller.

To restore the pressure difference accelerating the filtration, the filtrate peeling tube (7) is now swung out again and liquid is poured into the ring cup (13) through the backwashing tube (6). This creates a reverse pressure drop from the collecting chamber (11) to the housing interior from the liquid column Δ h - and consequently displaces the gas from the collecting chamber (11) through the bore (17) and the check valve (18). This process results in a short-term reduction in the filtration speed because it e.g. can be accomplished in 20 s. The peeling tube (7) is then swiveled in again, whereby the check valve (18) closes automatically and Δ h + again assumes a maximum value.

According to Figs. 2 and 3, a siphon device is used instead of the check valve (18). For this purpose, the horizontal branch (19) of the bore (17) is connected to a down pipe (20), the lower end of which (21) in the siphon cup (21). To achieve the desired valve action, liquid is filled into the siphon cup (21) through the refill tube (22). The refill tube (22) can also take over the function of the backwash tube (6) because the liquid overflowing from the small siphon cup (21) gets into the ring cup (13).

Fig. 2 shows the device in the "filtering" operating state. Because in this case the internal pressure of the centrifuge housing is greater than the pressure in the collecting chamber (11), the two liquid columns Δ h + generate the same, hydrostatic pressures. Because the liquid column Δ h + in the downpipe (20) is subject to a lower centrifugal acceleration than the column between the collecting space (11) and the ring cup (13), which is located radially further outwards, this inner column has a larger, radial extension. Both columns close the gas to the collecting space (11).

Fig. 3 shows the device in the "displacing" operating state. After gas has entered the collecting space (11) from the filtrate liquid and / or through the filter cake, this must be displaced. For this, according to the example, liquid is simultaneously filled into the siphon cup (21) and the ring cup (13) with the refill tube (22). As a result, the liquid column displaces Δ h - the gas which has entered the collecting space (11) through the downpipe (20). Because Δ h - in the siphon cup (21) can only assume a low value due to the low rim ring, the gas bubbles through this siphon cup into the interior of the housing. The rim of the siphon cup (21) can be kept very low because its cross-sectional area has a multiple of the cross-sectional area of the downpipe (20). Thus, in the operating state according to Fig. 2, a slight lowering of the level in the siphon cup (21) is sufficient to build up a liquid column Δ h + in the downpipe (20) corresponding to the pressure difference without it being necessary to add liquid through the refill pipe (22) .

Fig. 4 shows a pressure sensor (23) in the filtrate collecting space (11) which reports pressure measurement values to the control system via cable (24) and slip rings (not shown in the drawing) or a transmitter. As a result, the displacement of gas from the collecting space (11) into the centrifuge housing (1) can be controlled in a pressure-dependent manner. As soon as a selectable target pressure in the collecting space or under the filter medium (10) is exceeded, the filtrate peeling tube (7) swings out and liquid is filled into the ring cup (13) through the backwashing tube (6).

The advantage of the device according to the invention is not limited to the displacement of gas during centrifugation.

The device can also be used advantageously if the solid has been peeled apart from a residual layer. In this case, liquid had to be filled into the ring cup (13) when the peeling tube (7) was swung out, on the one hand to displace gas before the next batch and on the other hand to regenerate the remaining layer and the filter medium (10) by backwashing. If the resistance of the residual layer and filter medium was high, this process was time-consuming on the one hand and difficult to control on the other hand. In the case of large resistances, and possibly different for each batch, the volume flow of the liquid supplied would have to be adapted to this resistance. If the volume flow was too large, some of the liquid ran unused into the centrifuge housing via the rim ring of the ring cup (13). If the collecting space (11) was still largely filled with gas, a considerable pressure could arise against the filter medium (10) due to the length of the liquid column Δ h, until the filter medium was damaged. With the device according to the invention, the pressure in the collecting space (11) can only be as high as the resistance of the gas outflow device. Only when the liquid reaches the filter medium (10) from the collecting space (11) does the pressure difference still work remaining small column Δ h - and the filter medium (10) is flowed through.

The liquid supplied to the ring cup (13) can be metered precisely due to the new device and an ineffective overflow via the rim ring of the ring cup (13) is avoided.

Claims (6)

1. Centrifuge with a coaxial filtering centrifugal drum and with a radially outside of the filtering means, equipped with at least one discharge opening for filtrate, whereby a co-rotating siphon device is connected to the collecting space, which temporarily prevents gas from entering the collecting space, characterized by at least a gas discharge line (17) which connects the collecting space (11) to the centrifuge housing (1) and which opens into a device for the pressure-dependent discharge of gases which have penetrated through the filter medium (10). 2. Device according to claim 1, characterized in that the device for pressure-dependent gas discharge from the collecting space (11) is a check valve (18) known per se. 3. Apparatus according to claim 1, characterized in that the device for pressure-dependent gas discharge is a liquid-fillable, with the centrifuge drum (9) co-rotating siphon (20, 21). 4. The device according to claim 1, characterized in that means for supplying liquid through an annular cup (13) are provided, with which in the annular space (11) penetrated gases can be displaced by the device for pressure-dependent gas discharge. 5. Device according to claims 1 and 3, characterized by a refill tube (22) for the siphon cup (21). 6. The device according to claim 1, characterized by a pressure sensor (23) in the collecting space (15).

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