DE8438010U1 - Liquid filter with hydraulically driven backwashing device - Google Patents

Description

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HATLJCK, SCHMITT JJJRAzJ ₁ LfS, JWEjHH ¹ JERT, DÖRING

HAMBURG Wed) NCHIEK * NUSSHL * 3OHF PATKNTANWÄI.TF, · NEUBB WAI.li 41 ■ 2000 HAMHUHC HB Dipl.-l'hys. W. SCHMITZ - Dlpl.-Ing. B. GRAALFS

New WnIl 41 ■ 2000 Hamburg Telephone + telecopier (040) 3Θ 67 55

August G. Koch Toi "ob ii 7"> m _P "id

Maschinenfabrik ΐ) ΐρΐ.-ΐηκ · n. Iiauck - nipL-inj *. w.wehnbrt

50/52 MoznmimlSe 23 8000 Munich

Telephone + telecopier (08B) 53U2 3H 1 Telex O5 21B 563 pamu d

DrMiIB. W. DORING Akten7Pirhpn · R RA ^ R Π1Π 1 K-Wilhclm-HIn «41 · 40OO Düsseldorf

File number. G 84 38 010.1 Telephone (0211) 57ro27

Hamburg. February 14, 1986

Liquid filter with hydraulically driven backwashing device

The invention relates to a liquid filter according to the preamble of claim 1.

Such liquid filters are advantageous because of the The flushing gap only takes up a small part of the entire filter surface and therefore backwashing without interrupting the Filtration process and at the same time without a disruptive strong reduction in the FiItrationsstromes with a relatively low purge flow, can be carried out. Since the filter surface is moved away from the rinsing gap (or the rinsing gaps) must be, such liquid filters require one Drive for the backwash device. An electric gear motor is usually provided for this. This requires

European Patent Attorneys Admitted to the European Patent Office Deutsche Bank AG Hamburg, No. O5 / 28-497 (BLZ 2OO 7OO 0O) - Postscheck Hamburg 2842-208 Dresdner »! 54nk AG; i? Lftnbu ^ ,, Sir., EE | 3eO35 (BLZ 2OO 8OO 00)

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however, the supply of electrical energy and the necessary for it Security measures that are often found uncomfortable. The invention is therefore based on a liquid filter, in which a hydraulic drive device is provided for rotating the flushing head.

In a known liquid filter of the type specified (DE-OS 33 03 912) is a hydraulic motor installed on one end of the filter housing as the hydraulic drive device provided, whose output gear is coaxially coupled to the flushing head. As a drive fluid that is from the Filter leaking filtrate used. This known liquid filter requires one for the hydraulic motor considerable additional structural effort and space requirements.

The present invention is based on the object of providing a liquid filter with a hydraulically driven backwash device to create, in which the structural effort and space requirements are reduced.

According to the invention, this object is achieved with a liquid filter according to claim 1.

In the liquid filter according to the invention is for hydraulic drive device neither a separate construction

additional space required there is no need for line connections that only serve the hydraulic drive. The required drive power is less than with an attached hydraulic motor. There is enough on the flushing head between its axis and the flushing gap If radial space is available for structural design, there are no difficulties in using the flushing head as hydraulic design drivable rotor.

Both the filtration flow and the flushing flow can be used as the drive medium for the flushing head the flushing flow is relatively large, the drive power can be applied with it, and it then becomes the The flushing head is preferably designed to be driven by the flushing flow. If, on the other hand, only a relatively small amount Coil current is present, in particular with a very narrow or small flushing gap, it is generally more expedient to use the Train rinsing head to be driven by the filtration flow.

■ The invention, embodiments of the invention and fiction i

\ according to achievable advantages are in the following based on

H Embodiments in conjunction with the drawings

pt described in more detail.

Fig. 1 is a very schematic axial section partial illustration

position of a liquid filter according to the invention,

the section along the line I-I of FIG runs.

FIG. 2 is a schematic partial radial section illustration corresponding to the section plane II-II of FIG. 1.

FIG. 3 is a schematic perspective partial illustration of another embodiment of the rotor of a rotor according to the invention Filters.

Fig. 4 is a schematic perspective view another embodiment of a rotor.

5 is a schematic perspective partial illustration of a further possible embodiment.

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FIGS. 1 and 2 show a schematic representation of a liquid filter with a cylindrical filter housing 1 with an axis 3 and two transverse walls 5 and 7, of which the transverse wall 5 has a downwardly adjoining entrance space and the transverse wall 7 represents an upper cover which is sealed with a circumferential wall 11 of the housing 1 is connected, for example as shown in a flange connection 13 - In the circumferential wall 11 is an output connection 15 arranged for the purified filtration stream. In the circumferential wall of the entrance room 9 is located an input connection 17 for the unpurified filtration stream (the pulp). The filtration flow is through in FIG Arrows 19 indicated.

In the filter housing 1 there is arranged a filter element 21 through which the filtration flow 19 can flow and which is rotationally symmetrical to the axis 3 and has a hollow cylindrical shape in the illustrated embodiment. Through the filter element 21, the filter housing 1 is divided into an inner inlet space 23 and an outer outlet space 25. The input space 23 is via a circular opening 27 located in the transverse wall 5 with the input space 9 and the Input terminal 17 connected. The output space 25 is connected to the output connection 15.

I «I · I

τ. .6 - '

A rotatable about axis 3 is located in the filter housing Rinsing head 29, which is used to form a localized rinsing flow opposite the filtration flow 19, which is shown in FIG 1 is indicated by the arrows 31, has a flushing gap 33; this is close to the in relation to the filtration flow 19 upstream of the filter element 21. In the rinsing head 29, a rinsing line 35 is connected to the rinsing gap 33, which can be optionally shut off Flushing valve 37 leads to a drain area 39 in which a lower pressure prevails during filtration than on the downstream side (outlet side) of the filter element 21 with respect to the filtration flow 19 In the illustrated embodiment, it is assumed that the drainage area 39 is at atmospheric pressure.

The rinsing head 29 itself serves as the hydraulic drive device for rotating the rinsing head 29; he is as one of of the fluid present in the filter designed hydraulically driven rotor. In the illustrated embodiment more precisely, the flushing head is designed to be driven by the flushing flow. From the possible constructive solutions for this the embodiment shown is advantageous because of its simplicity; while the flushing head is used to generate a driving reaction torque from the flushing flow 19 formed. This is achieved in a very simple way by

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that a flushing line end portion 41, which has a radial Distance to the flushing gap 33 runs, in the radial section (Fig. 2) has a curvature that deflects the flushing flow in one direction. This achieves that the flushing head in the manner of a seafarer's sight Water wheel can be driven by the reaction force of the flushing flow.

In the embodiment shown, the is to deflect of the flushing flow 31 serving curvature in the area of the flushing gap 33, that is, at the radially outer end of the transverse to the axis 3 lying flush line end section 41, concentrated, and in that the flushing line has a rounded bend 43 in this area. This will increase the reaction force generated with a long lever arm.

It is advantageous if the flushing head is used to generate around ί
its axis 3 symmetrically distributed driving forces

ι educates is. This means that the bearings of the flushing head, both

For example, the upper bearing 45 shown in Fig. 1, less burdened. The lower bearing of the flushing head is not shown in FIGS. In the case of the Embodiment is for the reasons of symmetry mentioned

' _λ already described flushing gap 33 a diametrically opposite

^{] associated} flushing gap 47, which is connected to both end sections 41 and via a flushing line end section 49

! 49 common axial flushing line section 51 connected

is. The flush line end portion 49 is symmetrical to that

End section 41 is formed and accordingly also contains a kink 53- The flushing line end sections 41 and 49 are arranged in two radially opposite vanes 55 and 57, which merge in one piece into a hub body 59 in the embodiment shown. This takes the The flushing head takes up little space and only slightly hinders the filtration flow 19.

In Fig. 1, an optionally actuatable brake 61 is indicated, which acts on a stub shaft 63 of the hub body 59 which is carried out in a sealed manner through the transverse wall 7. In general, however, such a brake is not required so that the illustrated implementation of a hub stump and the upper bearing of the flushing head 29 are omitted can be arranged entirely on the inside of the transverse wall 7.

During operation, the liquid to be filtered flows over the Inlet connection 17 into the inlet chamber 9, through the opening 27 into the inlet space 23, through the filter element 21 into the output space 25 and out of this through the output connection 15 from. On the inside of the filter element 21 the filtered impurities collect. As soon as the valve 37 located in the flushing line is opened, there is a flow Filtrate back through the rinsing gaps 33 and 47 and washes away the impurities lying in front of the gaps the surface of the filter element 21 away. The impurities

•••••• Ο ·· «« · Μ

with the flushing flow via valve 37 into the ** Drainage area 39 passed. At the same time, the reaction effect causes that through the radial flushing line end sections 41 and 49 of the flushing stream flowing through the flushing head 29 set in motion in the direction of arrow 65; the rinsing gaps 33 and 47 move the entire inner surface of the |

Filter element 21 off. The rotation of the flushing head 29 takes place relatively slowly because in the liquid-filled f There is considerable flow resistance in the filter. The slow turning is desirable in order to achieve a sufficient flushing effect and low wear on the bearings of the flushing

i head 29 ensure. As soon as the valve 37 is closed | the backwashing stops and the rinsing head 29 remains stand.

As can be seen without further ado, the drive of the flushing head 29 is negligible in the illustrated filter Effort achieved, namely only through a corresponding design of the flushing line end sections 41 and 49. Also, no additional space is required.

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• ■ · · M * 4 W ·

Figures 3 to 5 show other embodiments. It the same reference numerals as are used for components that occur with a corresponding function in FIGS. 1 and 2 used there, but with the respective prefix Figure no. In this respect, in order to avoid repetition, reference is made to the above description of FIGS. 1 and 2 taken.

Fig. 3 shows an embodiment in which the wings 355 and 357 of the flushing head 329 are curved as a whole; the facilitates manufacture.

4 illustrates an embodiment in which the flushing head 429 is designed to be driven by the filtration flow. The wings 455 and 457, in which the flushing line end sections are provided, run in radial section in essentially radial, so that no reaction forces arise. To be driven by the filtration flow 419, in principle at least one inflow surface acted upon by the filtration flow in a driving manner can be provided on the flushing head. The embodiment according to FIG. 4 is designed to be driven by an axial flow component 71 of the filtration flow and for this purpose it has two inflow surfaces 73 and 75 which are arranged at an angle to the direction of the axis 465. The design is simplified in that the flow surfaces are provided on the wings 455 and 457, respectively. In the

... / 11

4, the flushing gap 433 provided at its outer end is indicated in the lower part of the wing 455. At this The construction method, therefore, the flushing gap and the driving inflow surface are combined into a simple construction.

In the embodiment according to FIG. 5, the structure is similar to that according to FIG. 4, but the flushing head is 529 to drive both by an axial component 571 of the filtration flow and by deflecting the flushing flow educated. For this purpose, the vanes 555 and 557 also used there are both radial and radial axially curved »

It goes without saying that the design of the inflow surfaces has to be based on the flow pattern of the filtration flow.

... / 12

summary

Liquid filter with hydraulically driven backwash device

Liquid filter with hydraulically driven backwashing device, with a filter element that is rotationally symmetrical to an axis and through which a filtration stream can flow, a rinsing head rotatable about the axis, which borrowed limited to form a flow opposite to the filtration flow Flushing flow at least one flushing gap located in front of the side of the filter element upstream with respect to the filtration flow and one with the flushing gap having connected, optionally lockable flushing line, "wherein the flushing line leads to a drainage area, in which during the filtration there is a lower pressure than that with respect to the downstream filtration flow Side of the filter element, the flushing head being designed as a rotor that can be hydraulically driven by the liquid.

Claims (12)

1. Liquid filter with hydraulically driven backwashing device, with a rotationally symmetrical to an axis (3) through which a filtration stream (19) can flow Filter element (21), a rinsing head (29) rotatable about the axis (3), which is used to form a dem Filtration flow (19) opposite locally limited winding flow (31) at least one ^ or the with respect to the Filtration stream (19) upstream side of the Flushing gap (33, 47) lying on the filter element (21) and an optionally lockable one connected to the flushing gap Has flushing line (35), the flushing line (35) leading to a drainage area (39) in which during the filtration a lower pressure prevails than that downstream with respect to the filtration flow (19) Side of the filter element (21), characterized in that the flushing head (29) as one of the liquid hydraulic drivable rotor is designed. 2. Filter according to claim 1, characterized in that the flushing head (29) is designed to be driven by the flushing flow (33) 1st. 3. Filter according to claim 2, characterized in that the flushing head (29) for generating a driving reaction ... / 13 Torque from äem Epülstrom (33) is formed. 4. Filter according to claim 3, wherein in the flushing head (29) at least one flushing line end section (41, 49) a radial distance to a flushing gap (33, 47) § runs, characterized in that the flushing line § End section (41, 49) in radial section a flushing j stream (33) has a unidirectional deflecting curvature. r 5. Filter according to claim 4, characterized in that the for deflecting the flushing stream (33) serving curvature in the Area of the flushing gap i33, 47) is concentrated. 6. Filter according to one of the preceding claims, characterized in that the flushing head (429; 529) for driving is formed by the filtration flow. 7. Filter according to claim 6, characterized in that the rinsing head (429) has at least one inflow surface (73, 75) acted upon by the filtration flow as a driving force. having. 8. Filter according to claim 7, characterized in that the inflow surface (73, 74) is formed in a wing (455, 457) is. ... / 14 9. Filter according to claim 8, characterized in that a flushing gap (433) is provided at the end of the wing. 10. Filter according to claim 9, characterized in that the Wing (555, 557} is axially and radially curved. 11. Filter according to one of the preceding claims, characterized in that the flushing head for generating to its axis is designed symmetrically distributed driving forces. 12. Filter according to one of claims 8 to 10 and 11, characterized in that the flushing head has two radially opposite one another Has wings (55, 57). ./15