EP3849688A1 - Filter medium for fluid filtration, and method for producing a filter medium and fluid filter - Google Patents

Abstract

The invention relates to a filter medium for fluid filtration, having at least two layers, at least one coarse filter layer (16) and a fine filter layer (17) arranged downstream of the coarse filter layer (16) in the flow direction (13). The coarse filter layer (16) and the fine filter layer (17) are connected together without using chemical binders, and the coarse filter layer (16) and the fine filter layer (17) each has a polymer fleece made of thermoplastic polymer fibers, wherein the fineness of the polymer fibers in the fine filter layer (17) is greater than the fineness of the polymer fibers in the coarse filter layer (16). According to the invention, the thermoplastic polymer fibers of the coarse filter layer (16) and the thermoplastic polymer fibers of the fine filter layer (17) are melt-blown fibers.

Description

 Filter medium for fluid filtration, method for producing a filter medium and fluid filter

The invention relates to a filter medium for fluid filtration, a method for producing a filter medium and a fluid filter.

It has long been known to use filter media consisting of nonwovens for the filtration of liquid and / or gaseous fluids. The variation options and economical manufacture of the nonwovens enable them to be adapted to almost all filtration tasks.

DE 102 21 694 A1 discloses a multi-layer structure of a filter medium which is used especially for vacuum cleaner bags. Here, a coarse layer as a dust storage layer was placed in front of a fine filter layer made of meltblown fleece. With sufficient dust storage, the fine layer ensures good separation of even fine dust particles. However, the structure produced in this way is not mechanically stable, so that a support layer is necessary on the downstream side in order to achieve mechanical strength. The result is a complex, multi-layered structure, with the adhesive bond of the individual layers using adhesive negatively influencing the air permeability. If less adhesive is used, the mechanical stability is again insufficient.

DE 20 2007 008 372 U1 describes a filter medium for air and liquid filtration. The filter medium comprises a coarse filter layer made of thermoplastic staple fiber nonwoven and a fine filter layer

Meltblown fibers, the meltblown fibers being connected to the staple fibers of the coarse filter layer by means of pressure and heat at defined embossing points they are. The layers of the composite are joined together purely thermally using pressure and heat without the aid of adhesives.

The object of the invention is to provide a filter medium or a fluid filter which is simple to produce inexpensively and which has separation capacities which are at least equal to those of the filter media or filters known from the prior art. It is also an object to provide a method for producing a filter medium which is more economical than conventional production methods.

This object is achieved by a filter medium with the features of independent claim 1, a method for producing a filter medium with the features of claim 14 and a fluid filter with the features of independent claim 18.

The filter medium according to the invention is characterized in that both the thermoplastic polymer fibers of the coarse filter layer and the thermoplastic polymer fibers of the fine filter layer are meltblown fibers.

Both filter layers, ie both the coarse filter layer and the fine filter layer, each consist of a meltblown fleece. Such meltblown nonwovens can be produced in a simple and inexpensive manner by the so-called meltblow process. In a meltblow process, thermoplastic polymers are melted, in particular with the aid of extruders, and then pressed through a large number of small, very fine nozzles. The polymer melt is caught at the nozzle outlet or immediately below by hot air, which stretches, swirls, and solidifies the emerging filaments in the still liquid state within a few milliseconds. Due to the force of the hot air flow and the fineness of the filaments, they tear very often, so that more or less long, very fine filament sections can be deposited directly into a fleece on a conveyor belt. Accordingly, in the filter medium according to the invention, the coarse filter layer and also the fine filter layer are produced using the meltblow process, so that the same production process can be used both for the coarse filter layer and for the fine filter layer. Furthermore, it is possible to use meltblow processes, as described above, for the production of both the coarse filter layer and the fine filter layer. Compared to other manufacturing processes for filter layers made of thermoplastic polymer fibers, such as the segmented-pie process, the meltblow process is more cost-effective. The variation in the fineness of fibers between the coarse filter layer and the fine filter layer can be set, for example, by the choice of the nozzle openings or the flow rate of the hot air. In contrast to the above-described prior art, in which the composite of a staple fiber fleece and a

According to the invention, meltblown nonwoven, which can be produced by different manufacturing processes, is the same type of nonwoven, namely

Meltblown nonwovens are used, whereby mixed components as in the prior art are avoided. Such a composite is therefore more economical to manufacture. The filter medium according to the invention is essentially, in particular 100% synthetic. Compared to a composite in which a layer contains glass fibers, this is particularly advantageous when such a filter medium is used in motor vehicle filters, in particular motor vehicle filters in injection systems, since the glass fiber breakage which damages the filter does not occur here.

In a particularly preferred manner, the fiber diameter of the meltblown fibers in the coarse filter layer is in the range from 0, dmiti to 5.0 pm, in particular 1.0 to 3 pm. The meltblown fibers of the fine filter layer are preferably nanofibers whose fiber diameter is in the range from 100 pm to 500 pm, in particular 150 pm to 400 pm.

In a particularly preferred manner, the meltblown fibers of the coarse filter layer and / or fine filter layer are polyester fibers. The polymer used in the meltblown process is therefore preferably a polyester. The polyester fibers are preferably polyterephthalate fibers, preferably polyalkylene terephthalate fibers, in particular

Polyethylene terephthalate (PET) and / or polybutylene terephthalate (PBT) fibers. However, it is also possible to use polypropylene, polyamide, polycarbonate or thermoplastic polyurethane fibers.

The selection of the suitable polymer depends on the application of the filter medium. Because of their high melting point and high resistance, polybutylene terephthalate fibers are particularly suitable for the filtration of hot and aggressive liquids, e.g. Lubricating oil or biodiesel. In contrast, air filtration applications tend to use polypropylene or polycarbonate fibers.

In a development of the invention, the fiber diameter distribution of the meltblown fibers in the coarse filter layer and / or fine filter layer is uniform.

Alternatively, it is possible that the fiber diameter distribution of the

Meltblown fibers in the coarse filter layer and / or fine filter layer has a gradient, the fiber diameter in particular continuously decreasing in the direction of flow.

In a further development of the invention, a protective layer of nonwoven fabric is provided in front of the coarse filter layer in the direction of flow and is connected to it without the use of chemical binding agents. The fibers of the nonwoven fabric of the protective layer are expediently thermoplastic polymer fibers, in particular likewise meltblown fibers, as a result of which the protective layer can also be produced by the melt flow process.

In this case, the functionally different layers, protective layer, coarse filter layer and fine filter layer can be produced particularly economically by the same manufacturing process.

In a particularly preferred manner, the fine filter layer has a plurality of filter layers which are connected to one another without the use of chemical binders Meltblown fleece, the average of the geometric pore size of the meltblown fleece decreasing in the flow direction from filter layer to filter layer.

In a particularly preferred manner, the fine filter layer has a pre-separation layer made of meltblown nonwoven with pores with a pore size of 5miti to 15miti, in particular 8miti to 12miti.

The fine filter layer particularly preferably has a flake deposition layer as a meltblown nonwoven with pores with a pore size of 1 miti to 8mhh, in particular 3miti to 6miti.

In a further development of the invention, a support layer made of nonwoven fabric is provided downstream of the fine filter layer and connected to it without the use of chemical binders. The fibers of the nonwoven fabric of the protective layer preferably consist of thermoplastic

Polymer fibers. It is possible that the thermoplastic

Polymer fibers are spunbond, wetlaid and / or carded polymer fibers. In a further development of the invention, the protective layer has a pleating.

The invention further comprises a method for freezing a filter medium according to one of claims 1 to 13, which comprises the following steps:

- arranging the at least one coarse filter layer and the at least one fine filter layer one above the other, - introducing energy into the loose composite of coarse filter layer and fine filter layer in such a way that the meltblown fibers partially melt and coarse filter layer and fine filter layer are connected to one another, the connection of the coarse filter layer and the fine filter layer without the use of chemical binders. It is possible that the meltblown fleece of the coarse filter layer is first produced by the meltblown process in a meltblow system and independently of which, in particular at another station of the meltblow plant, the

Meltblown fleece of the fine filter layer. In this way you can run in parallel

Prepare meltblown nonwovens for the coarse filter layer and meltbown nonwovens for the fine filter layer, which are then placed on top of one another in a next step and connected to one another by the input of energy and melting of the fibers. The other functional layers, in particular the protective layer, can also be produced in the meltblow system, provided that they are also designed as meltblown nonwovens. To produce the composite, which then comprises more than two layers, the various functional layers are then placed one on top of the other and connected to one another by the introduction of energy and melting of the meltbown fibers.

Alternatively, however, it would also be possible to provide the composite of coarse filter layer and fine filter layer at the same time as the meltblown nonwoven of the coarse filter layer and the meltblown nonwoven of the fine filter layer. For this purpose, it would be conceivable that meltblown fibers for the coarse filter layer or alternatively meltblown fibers for the fine filter layer are first produced in the meltblow system and placed on a conveyor belt. The unconsolidated meltblown fibers can then be used for the

Meltblown fleece of the coarse filter layer or alternatively of the fine filter layer are conveyed to a second work station, where meltblown fibers for the fine filter layer, if the meltblown fibers of the coarse filter layer have been deposited beforehand, or meltblown fibers for the fine filter layer if meltblown fibers for the fine filter layer have previously been deposited Meltblown fibers are stored. The next step would then be to consolidate and connect the loose layers by introducing energy and melting the meltblown fibers.

If the composite is to comprise more than two layers, then the necessary work stations should be provided in accordance with the number of layers, so that the individual meltblown fibers of the different layers can be layered one on top of the other. However, it would also be conceivable to produce individual functional layers separately, for example a support layer that does not consist of meltblown fibers. Layer and then lay it on the loose composite of the fiber layers already produced. It would also be conceivable to produce a separately produced functional layer, for example a protective layer on the upstream side, and to deposit the meltblown fibers for the coarse filter layer and fine filter layer thereon.

In a development of the invention, the energy is introduced by pressing at elevated temperature and pressure.

In a particularly preferred manner, the pressing is carried out at elevated temperature and pressure by means of thermal calendering with the aid of a thermal calender.

Alternatively, it is possible for the energy to be introduced by ultrasound, preferably using an ultrasound calender.

The invention further comprises a fluid filter for the filtration of a fluid, for example air or fuel, with an inflow opening for raw fluid and an outflow opening for filtered pure fluid, which is characterized in that at least one in one flow direction between the inflow opening and the outflow opening from the inflow opening to the outflow opening of fluid to be filtered through which filter medium can be arranged according to one of claims 1 to 13. Depending on the selection of the meltblown fibers, the filter medium is suitable for a wide variety of applications, so that it can be used, for example, as an air filter, for example in intake systems of motor vehicles, or alternatively as a liquid filter, for example as a fuel filter.

A preferred embodiment of the invention is shown in the single figure and is explained in more detail below. The figure shows: a section in the flow direction through a preferred embodiment of the filter medium according to the invention, the filter medium being shown only schematically.

The single figure shows a preferred embodiment of the filter medium 11 according to the invention. The filter medium 11 shown by way of example in this case consists of five layers or layers. The filter medium can be assembled in almost any way and can therefore be used, for example, as a filter material in a flat surface filter, bag filter, cartridge filter or depth filter for air filtration or belt filter, candle filter or drum filter for liquid filtration.

A fluid filter with such a filter medium 11 has at least one inflow opening (not shown), through which raw fluid to be filtered enters the fluid filter. The fluid can be gaseous media such as air or other gases to be filtered, or alternatively liquids. The raw fluid to be filtered reaches the raw fluid side 12 of the filter medium 11 and flows through it in a flow direction 13 and exits the filter medium 11 filtered on a clean fluid side 14.

The raw fluid to be filtered flows through the various functional layers of the filter medium 11 one after the other. According to a preferred exemplary embodiment, the raw fluid to be filtered first passes into an air-permeable protective layer 15, which is designed as a meltblown fleece and protects the coarse filter layer 16 behind it from abrasion. The filter effect in the relatively thin protective layer is relatively low. In the example shown, the protective layer expediently consists of meltblown fibers

Polybutylene terephthalate or alternatively polyethylene terephthalate.

After passing through the protective layer, the still practically unfiltered raw fluid reaches the coarse filter layer, which can also be referred to as a particle or dust storage layer. This is a voluminous meltblown layer, i.e. a meltblown fleece. As fibers for the Meltblown fleece in the described embodiment

 Polybutylene terephthalate fibers or alternatively polyethylene terephthalate fiber is used. The fiber diameter of the meltblown fibers in the coarse filter layer is in particular in the range from 1.0 pm to 3.0 mm. Since the coarse filter layer is a relatively voluminous meltblown layer, it makes sense for the fiber fineness of the meltblown fibers to have a gradient within this layer, the fiber fineness increasing in the flow direction.

After the passage of the pre-filtered raw fluid, which is freed from coarse particles that are retained in the coarse filter layer, the raw fluid enters a fine filter layer 17.

The fine filter layer 17 consists of two layers, a pre-separation layer 17a made of a meltblown fleece and a main separation layer 17b arranged in the flow direction 13 after the pre-separation layer also made of a meltblown fleece. Polybutylene terephthalate fibers or alternatively polyethylene terephthalate fibers are used as meltblown fibers of both the pre-separation layer 17a and the main separation layer 17b. The fiber structure of the pre-separation layer 17a differs from the fiber structure of the main separation layer 17b. The meltblown fleece of the pre-separation layer 17a has pores with a pore size of dmΐti to 12mΐti. The meltblown nonwoven of the main deposition layer 17b, however, has smaller pores, namely those with a pore size of 3mΐti to 6mΐti.

The pore sizes can be determined using the so-called “bubble point test”. For this purpose, the porous body to be characterized, in this case the pre-deposition layer 17a and the main deposition layer 17b, is completely wetted with a test liquid, the surface tension of which is low and known. Then the sample is exposed to air on one side and the pressure is increased until the first bubble appears. This pressure is referred to as “bubble point pressure”. Taking into account the surface tension and the pressure required to open the first pore, the apparently largest pore can be calculated using the following equation, assuming circular pores: io d _x = 4öcoscp / Ap d _x : apparent pore diameter [m]

d: surface tension [N / m]

coscp: wetting angle [-]

Dr: pressure difference at the filter [Pa]

The diameter (d _x ) denotes a circular pore, the area of which is equal to that of the real irregularly shaped pore. Meltblow nonwovens not only have a discrete pore size, but also a pore size range. The pore size spectrum can be determined using an automated measuring device. The materials are also tested in accordance with the DITF technical instructions for nonwovens "Determining the pore size on the" Coulter Porometer ". “Coulter Porofil” is used as the test liquid. The samples are punched out to a diameter of 25 mm (4.9 cm ² ) before the measurement. The measuring range extends from 0.07mΐti to 300mΐti (theoretical pore size).

As already mentioned, the fiber unit of the fine filter layer, ie both in the pre-separation layer 17a and in the main separation layer 17b, is larger than the fiber fineness in the coarse filter layer. The fiber diameter of the meltblown fibers in the fine filter layer is in the range from 150nm to 400nm.

As shown in particular in the single figure, a support layer 18 is arranged after the fine filter layer 17, which in the example is a spunbonded fabric made of spunbonded fibers. Of course, it is also possible to construct the filter medium from more than five or less than five functional layers. A coarse filter layer and a fine filter layer downstream in the direction of flow are required. It is also possible, for example, for the coarse filter layer to have a plurality of layers which differ from one another in terms of fiber properties (fiber diameter, fiber fineness). The filter medium according to the invention is produced by the

Meltblow process. A characteristic meltblow system (not shown) has an extruder in which plastic granules are melted. In the example here, polybutylene terephthalate granules or alternatively

Molten polyethylene terephthalate granules. The melted granulate is continuously fed via a spinning pump to a nozzle pack, which has a melt distributor, melt filter, various temperature and pressure measurement errors and at least one meltblow nozzle. The polymer melt extruded from the nozzle is captured immediately after exiting by a converging temperature air stream of the so-called primary air, which mixes with the ambient air, the so-called secondary air, immediately after the nozzle exits. The fibers that form here from the melt cool down on the way to storage and are collected as intertwined fibers in the form of a nonwoven. The deposit is usually made on an air-permeable structure such as a deposit belt or a sieve drum, which is additionally provided with a vacuum. This serves to keep the fibers on the shelf and to remove excess primary air.

In the specific example, the fibers for the coarse filter layer are first laid. Leaking polybutylene terephthalate or alternatively

Polyethylene terephthalate is deposited in the manner described above on a previously produced or separately produced meltblown nonwoven, which forms the protective layer. The loose composite created here is conveyed further and moved to a second work station, at which the meltblown fleece of the fine filter layer 17 is produced. First, the polybutylene terephthalate or alternatively

Polyethylene terephthalate fibers for the pre-separation layer 17a are placed on the loose composite of protective layer and coarse filter layer and then the fibers for the meltblown fleece of the main separation layer 17b.

In a subsequent step, the carrier fleece of the support layer 18 is then placed on the loose composite. The resulting loose composite of the protective layer 15, coarse filter layer 16, fine filter layer 17, with the pre-separation layer 17a and the main separation layer 17b and the support layer 18 are then connected to one another by means of thermal calendering. For this purpose, the loose bond is fed into a thermal calendar; the loose composite passes through calender rolls, at least one of which is a

Engraving roller is. The distances between the individual connection points must be selected so that they are sufficiently far apart that the filter properties, such as fluid permeability and particle storage capacity, remain largely unaffected. On the other hand, the distances between the individual connection points must be too small that the downstream meltblown can only expand slightly, i.e. the risk of bursting is minimized. For example, it is possible to engrave calenders with an engraving depth of> 1 mm and max. 3 mm. The connection area (press area) is expediently not more than 25% in order to ensure the air permeability of the composite. The connection area is in the range of 12% to 18% based on the total filter area.

A comparison of the technical data of a filter medium according to the invention with the known prior art is given below. The product according to the invention has the following structure:

Upstream side (coarse filter layer):

• Meltblown fleece with a weight of 100g / m ²

 Polybutylene terephthalate deposited on a PET carrier layer.

The PBT meltblown has an average fiber titer of approximately 1.8dtex

 (Decitex)

The PET carrier is made of a thermally bonded carded fleece made of a bicomponent staple fiber CoPET jacket and with PET core formed. This fiber has a titer of approximately 4.4dtex (decitex) and a staple length of 51 mm. The fleece has a weight per unit area of approximately 20 g / m ² . The hardening area is 100%.

Downflow side (fine filter layer): · Meltblown fleece with a weight of 100g / m ² on polybutylene terephthalate laid on a PET carrier layer

• The PBT meltblown has an average fiber titer of approximately 1.0dtex

• The PET carrier layer is formed from a thermally bonded carded fleece made from a bicomponent staple fiber CoPET jacket and with a PET core. This fiber has a titer of approximately 4.4dtex and one

Stack length of 51 mm. The fleece has a weight per unit area of approximately 20 g / m ² . The hardening area is 100%.

Engraving: Calender engraving with a press area share of 6% with 6.9 points / cm ²

Comparative example according to the prior art:

Upstream side (coarse filter layer): Polybutylene terephthalate (PBT) meltblown layer with a fiber distribution from 1.9 pm to 5.1 pm.

Downflow side (fine filter layer): Bi-component layer based on polyamide (PA) on a PET carrier layer with a fiber distribution from 0.45 pm to 2.4 pm.

Table: Comparison of the technical data:

It should be noted that the layer for the outflow side (fine filter layer) from the comparative example from the prior art is produced by a so-called segmented-pie process, which is more expensive than the meltblow process described, with which the layer for the outflow side is produced. diger and is associated with higher manufacturing costs.

Nevertheless, the material according to the invention is in no way inferior to the material from the prior art in terms of degree of separation. The dust storage capacity of the material according to the invention is increased compared to the prior art.

Claims

Expectations

1. Filter medium for fluid filtration, which has at least two layers, comprising at least one coarse filter layer (16) and a fine filter layer (17) arranged after the coarse filter layer (16) in a flow direction (13), the coarse filter layer (16) and the fine filter layer (17) are connected to one another without the use of chemical binders, and wherein the coarse filter layer (16) and the fine filter layer (17) are each a polymer fleece made of thermoplastic polymer fibers, the fiber fineness of the thermoplastic polymer fibers in the fine filter layer (17) being greater is the fiber fineness of the thermoplastic polymer fibers in the coarse filter layer (16), characterized in that both the thermoplastic polymer fibers of the coarse filter layer (16) and the thermoplastic polymer fibers of the fine filter layer (17) are meltblown fibers.

2. Filter medium according to claim 1, characterized in that the fiber diameter of the meltblown fibers in the coarse filter layer (16) is in the range from 0, dmhh to d, Omΐti, in particular 1, Omΐti to 3.0mΐti.

3. Filter medium according to claim 1 or 2, characterized in that the fiber diameter of the meltblown fibers in the fine filter layer (17) is in the range from 100 nm to 500 nm, in particular 150 nm to 400 nm.

4. Filter medium according to one of the preceding claims, characterized in that the meltblown fibers of the coarse filter layer (16) and / or

Fine filter layer (17) are polyester fibers.

5. Filter medium according to claim 4, characterized in that the polyester fibers are preferably polyterephthalate fibers

Polyalkylene terephthalate fibers, in particular polyethylene terephthalate (PET) and / or polybutylene terephthalate (PBT) fibers.

6. Filter medium according to one of the preceding claims, characterized in that the fiber diameter distribution of the meltblown fibers in the coarse filter layer (16) and / or fine filter layer (17) is uniform.

7. Filter medium according to one of claims 1 to 5, characterized in that the fiber diameter distribution of the meltblown fibers in the coarse filter layer (16) and / or fine filter layer (17) has a gradient, the fiber diameter in the flow direction (13) in particular continuously decreases.

8. Filter medium according to one of the preceding claims, characterized in that a protective layer (18) made of nonwoven fabric is arranged in the flow direction (13) in front of the coarse filter layer (16) and is connected to it without the use of chemical binding agents. whereby preferably the fibers of the nonwoven fabric of the protective layer are thermoplastic polymer fibers, in particular meltblown fibers.

9. Filter medium according to one of the preceding claims, characterized in that the fine filter layer (17) comprises a plurality of filter layers connected to one another without the use of chemical binders

 Meltblown fleece, the average of the geometric pore sizes of the meltblown fleece decreasing in the flow direction (13) from filter layer to filter layer.

10. Filter medium according to claim 9, characterized in that the fine filter layer (17) has a pre-separation layer (17a) made of meltblown fleece with pores with a pore size of 5mΐti to 15mΐti, in particular 8mΐti to 12mΐti.

11. Filter medium according to claim 9 or 10, characterized in that the

Fine filter layer (17) has a flake deposition layer (17b) made of meltblown fleece with pores with a pore size of 1 mΐti to 8mΐti, in particular 3mΐti to 6mΐti.

12. Filter medium according to one of the preceding claims, characterized in that a support layer (18) made of nonwoven fabric is arranged in the flow direction (13) after the fine filter layer (17) and is connected to it without the use of chemical binders, whereby preferably the fibers of the nonwoven fabric of the support layer (18) are thermoplastic polymer fibers, in particular spunbond, wetlaid and / or carded thermoplastic polymer fibers.

13. Filter medium according to claim 12, characterized in that the support layer (18) has a pleating. 14. A method for producing a filter medium (11) according to one of the preceding claims, comprising the steps:

Arranging the at least one coarse filter layer (16) and the at least one fine filter layer (17) one above the other,

Entry of energies into the loose composite of coarse filter layer (16) and fine filter layer (17), such that the meltblown fibers partially melt and coarse filter layer (16) and fine filter layer (17) are connected to one another, the connection of the coarse filter layer (16) and the fine filter layer (17) takes place without the use of chemical binding agents. 15. The method according to claim 14, characterized in that the energy input is carried out by pressing at elevated temperature and increased pressure.

16. The method according to claim 15, characterized in that the pressing is carried out at elevated temperature and pressure by means of thermal calendering with the aid of a thermal calender.

17. The method according to claim 14, characterized in that the energy input takes place by means of ultrasound, preferably with the aid of an ultrasound calender.

18. Fluid filter for the filtration of a fluid, for example air, with an inflow opening for raw fluid and an outflow opening for filtered pure fluid, characterized in that between the inflow opening and the outflow opening at least one in a flow direction (13) from the inflow opening to the outflow opening of fluid to be filtered

 through flowable filter medium (11) according to one of claims 1 to 13 is arranged.