EP1044050A1

EP1044050A1 - Method for filtering a liquid

Info

Publication number: EP1044050A1
Application number: EP98965744A
Authority: EP
Inventors: Karl-Günter BREMER; Karl Heinz BÜHL
Original assignee: Mann and Hummel GmbH; Filterwerk Mann and Hummel GmbH
Current assignee: Mann and Hummel GmbH
Priority date: 1997-12-04
Filing date: 1998-12-03
Publication date: 2000-10-18
Also published as: WO1999029396A1; CA2312794A1; US6555014B1

Abstract

The invention relates to a method for filtering a liquid and to a device for carrying out said method whereby at least one container is provided from which a filter auxiliary agent is fed to a dosing device by a delivery device, and the filter auxiliary agent is supplied to an injecting container and/or to a filter element via the dosing device.

Description

Process for filtering a liquid

description

The invention relates to a method for filtering a liquid according to the features of claim 1.

DE 35 37 384 discloses a method for cleaning liquid cooling lubricants. In these, a precoat filter is arranged in a circuit, and filter aids are used in the precoat filter with a highly surface-active and adsorbing substance. These filter aids are, for example, commercially available bleaching earths. A disadvantage of the system is that a filter cake must first be built up from the filter aid so that a sufficient filter fineness is produced. A high level of filter aids is therefore to be expected. Another disadvantage is that a precise dosing of the precoat is problematic due to turbulence and therefore the filtration result may be subject to very strong fluctuations.

The invention has for its object to provide a method and an apparatus for filtering a liquid, wherein the amount of filter aid is to be minimized and a high filtration quality is achieved in filtration systems.

This object is achieved by the features of independent claim 1 and, according to the device, by the features of claim 9.

The advantage of the method is that a precoat is not necessary, but filter aids are added to the dirty liquid to be filtered and a higher degree of cleaning can be achieved. According to an embodiment of the invention, it is proposed to ensure the open-pore structure by appropriate metering of the filter aid. What is important in this measure is, above all, an appropriate grain size of the filter aid or a corresponding pressure resistance of the filter aid in order to avoid caking.

According to one embodiment of the invention, the filter aid can be metered in batchwise or continuously. The vaccination is expediently carried out when the contamination is very low or the service life of a filtration system is to be extended. Filter aids can also be added when the system is not in operation and only the quality of the liquid has to be maintained.

A further development of the invention provides that the filter aid is premixed with dirt constituents or with the dirt liquid, so that the filter aid is better distributed. Both corn meal and cellulose can expediently be used. Vaccination with cellulose, in particular, achieves a filtration quality that is better than with the alluvial deposits previously used by diatomaceous earth or bleaching earth. Diatomaceous earth in particular should be avoided in the future as it is considered to be hazardous to health.

Another advantage of using corn meal or cellulose is that the residue can be easily disposed of. Cellulose, for example, burns almost without residue.

It has been shown that the invention can be used advantageously in various filter systems. The filter aid increases both the life of the liquid, for example an emulsion. A filter fineness of <15 μ is also achieved. The filter systems include, for example, gravity band filter systems, pressure band filter systems or vacuum filter systems.

Another variant of the method can be seen in the fact that a filter system is only partially washed up, ie the filter aid only in a certain area the effective filter area covered. This creates a kind of sidestream filtering. The main advantage is that two filters can be integrated in a single filter system. It is also possible to carry out the precoat in different densities. This also creates filters with different filter fineness.

According to a further development, the basic build-up of the filter aid represents an additional variant. In this case, only filter aid is initially entered, and then dirty liquid is added. This wash-up has the advantage that the high filter fineness is achieved right at the beginning of the filtration process.

In general, the invention has the following improvements over the previously known method:

Reduced consumption of filter aids,

Avoiding the use of health-endangering filter aids, e.g. B.

Diatomaceous earth in precoat filter systems,

Filtration quality improvement,

Replacement of precoat filter systems as current technology for high and highest quality filtration requirements when using cooling lubricants, both for oil and for suspensions,

Possibility of processing used oils,

Extension of the cooling lubricant maintenance intervals,

Reduction of the cleaning effort for the storage container

Cooling lubricants,

Mitigation of waste disposal problems,

Reduction of disposal costs.

These and further features of preferred developments of the invention are evident from the claims and also from the description and the drawings, the individual features being implemented individually or in groups in the form of subcombinations in the embodiment of the invention and in other fields, and can represent advantageous and protectable versions for which protection is claimed here. The invention is explained below using exemplary embodiments. It shows:

Figure 1 shows the schematic structure of a system for cleaning liquid

Cooling lubricants,

Figure 2 shows the variant of a system for cleaning liquid cooling lubricants.

Figure 1 shows the schematic structure of a system for cleaning liquid cooling lubricants. The cooling lubricant supplied by machine tools (not shown here) and loaded with chips and contaminants is introduced via lines 10, 11, 12 into a dirt container 13. From this dirt container 13, the liquid reaches a precoat filter system 16 via line 14 and a pump 15. In a precoat filter system, there are usually several candle filters. Such a precoat filter system is known for example from DE 29 08 625 A1.

The cleaned liquid leaves the system via line 17 and can be fed back to the machine tools via a clean tank and possibly additional pumps. A line 18 and a valve 19 are arranged at the discharge opening of the precoat filter system 16. When the valve 19 is opened, the dirt and the filter aid are conveyed into a container 20.

A filter aid for the alluvial coating, e.g. B. cellulose, comes from a container 21 to a conveyor 22. This conveyor has a metering device 23 and a screw conveyor 24. From here, the filter aid is metered into a container 25 which is filled with oil or suspension. The filter aid and the liquid are mixed with an agitator 26. This means that at the start of the filter, the precoat is provided and pumped to the filter. The precoat filter system is ready for use once the basic precoat has been completed. During the normal filtration cycle, the inoculation container 25 is together and simultaneously with the filtration cycle Oil vaccine substance is continuously or discontinuously added to the filtration circuit via line 27 and valve 28, ie oil vaccine substance is continuously or intermittently inoculated into the filtration circuit with an inoculation pump 29. In order to avoid unnecessary expenditure of energy, this is preferably done by injecting the inoculation substance via the pipeline 27 into the pipeline 14.

Due to the inoculation process, the dirty liquid pumped over the filter candles is constantly mixed with the inoculant, so that a mixture consisting of inoculum and dirt forms on the filter candles. By inoculating continuously or discontinuously with the inoculation suspension substance during the ongoing filtration, the porosity of the deposits on the filter candles or the property of the stratification increases and thus enables a very effective and high quality filtration quality. Vaccination also significantly extends the service life.

To form a precoat, as shown in the figure, the precoat is provided in a container 30 and from there is a conveyor 31 consisting of metering device 32 and

Screw conveyor 33 supplied. The screw conveyor device places the precoat in the container 34, in which there is oil or suspension. With the agitator 35, the precoat is mixed with the oil or the suspension and fed via line 36 and the valve 37 to the precoat filter system before the start of a filtration process. The basic precoat deposits on the filter candles and forms a first filter layer.

The subsequent inoculation of the supplied dirty liquid results in a better quality of the cooling lubricant, i. H. the degree of purity of the cooling lubricants increases.

The variant according to Figure 2 shows a structure in which certain parts of the system are duplicated, such as. B. the filter devices or certain feed pumps. The system consists of a clean container 38 in which cleaned cooling lubricants are located, a dirt container 39, two filter devices 40, 41, a vaccination device, consisting of an inoculation tank 42, a metering device 43, a wash-off tank 44 and a corresponding equipment with pumps and pipes. The cooling lubricant to be cleaned arrives from machine tools (not shown here) via lines 45, 46 to the dirt container 39. The dirty liquid is conveyed to the two filter devices 40, 41 via several pumps 48 and lines 49, 50. The supply of filter aids via the lines 51, 52 is provided on the suction sides of these pumps 48. The filter aid, for example corn meal, is made available in a container 53 and from there it reaches the inoculation container 42 via a conveyor 54 and a dosing screw 55. The inoculation container contains pure liquid. The filter aid is mixed with the pure liquid in this container. A mixer 56 is provided for this.

As already mentioned, the pure liquid with the filter aid reaches the suction side of the pumps 48 via feed pumps 57, 58 and the lines 51, 52. The dirty liquid now mixed with filter aid is fed to the filter devices 40, 41. Filter candles are arranged in the filter devices, for example, which have a certain filter fineness and on which the dirt is deposited. The cleaned liquid reaches the clean container 38 via the lines 59, 60 and can be conveyed from there via the pumps 61 and line 70 to the corresponding machine tools. To clean the filter devices 40, 41, compressed air is supplied via the lines 62, 63. This compressed air displaces the pure liquid and at the same time dehumidifies the filter cake that has formed through the filtration. The filter cake is fed via lines 64, 65 to a flushing tank 44. The dirt is removed from this flushing tank by means of the pump 66 to a pressure band filter 67. This pressure band filter separates the residual moisture from the sludge. The sludge is discharged into the container 68, the residual liquid reaches the dirt container 39 via the line 69.

Of course, different filter systems can be used with regard to the filter device. So there is a possibility Gravity filtration or vacuum filtration. In the case of vacuum filtration, the filter aid is applied to an endless belt. This endless belt passes through the filter container. The dirt accumulating on it is removed by appropriate scratching devices.

The filter aid can also be entered if there is no contamination. This is a maintenance filtration, which is particularly necessary on weekends and thus enables a longer service life of the cooling lubricant.

Claims

claims

1. A method for filtering a liquid with a filter element for separating dirt components from the liquid, at least one filter aid being added to the dirty liquid to be filtered and a higher degree of purity of the liquid to be filtered being achieved.

2. The method according to claim 1, characterized in that the filter aid achieve an open pore structure on the filter surface.

3. The method according to claim 1 or 2, characterized in that the addition of the filter aid is carried out batchwise or continuously.

4. The method according to any one of the preceding claims, characterized in that a mixture of filter aid and dirty liquid is made before the filtration process.

5. The method according to any one of the preceding claims, characterized in that the filter aid consists of corn meal or cellulose.

6. The method according to any one of the preceding claims, characterized in that the filtration is carried out in a gravity band filter system, a pressure band filter system or a vacuum filter system.

7. The method according to any one of the preceding claims, characterized in that a basic wash-up of a filter aid takes place.

8. The method according to claim 6, characterized in that the filter aid is partially supplied in a defined filter area and thus a bypass filtration is realized.

9. Device for performing the method according to one of the preceding claims, characterized in that a container is provided, from which filter aid arrives at a metering device with a conveying device and the filter aid is fed to an inoculation container or a filter element via the metering device.