EP4196250A1

EP4196250A1 - Drying of filter modules and filter housings using a frequency-guided microwave process

Info

Publication number: EP4196250A1
Application number: EP21770123.4A
Authority: EP
Inventors: Marcel Mallah
Original assignee: Fricke und Mallah Microwave Technology GmbH
Current assignee: Fricke und Mallah Microwave Technology GmbH
Priority date: 2020-08-12
Filing date: 2021-08-12
Publication date: 2023-06-21
Also published as: US20240035747A1; DE112021004239A5; DE102021121051A1; CN116472433A; WO2022033637A1

Abstract

The invention relates to a device for drying dialysis filter cartridges, candle filters and other enclosed filter systems, comprising a microwave chamber which is equipped with a filter module. The microwave chamber is characterised in that it separates regions of high and low microwave absorption in a contact-free manner. The regions of high energy absorption generally correspond to the middle region of the filter where the bundle of hollow fibres or the filter material is located. The regions of low absorption correspond to the microwave-sensitive end regions of the filter module. In order to dry the wet filter module, the microwave frequency with the maximum converted power is determined, then microwave energy is introduced at this frequency, and while the filter is drying, the reflected microwave power is continually determined and kept to a minimum by readjusting the microwave frequency. The water is removed from the module at the same time as an air or gas flow. The method requires a solid-state microwave generator with adjustable frequency, but then enables the quick and gentle drying of filter cartridges and other enclosed filter units such as candle filters. In particular, wastage caused by accidentally overheating the temperature-sensitive end regions of the filter housings and filter modules containing the seals and adhesive bonds is avoided.

Description

DRYING OF FILTER MODULES AND FILTER HOUSINGS WITH A FREQUENCY-CONTROLLED MICROWAVE PROCESS

The invention relates to a method for producing filter units containing a plurality of diaphragms or membranes, and a method and a device for drying such filter units after their functional testing.

TECHNICAL BACKGROUND

[002] Dialysis filter cartridges and their manufacture are known from EP 1 631 152 B1 and DE 102013 006 507 B4. The dialysis filter cartridges are required for blood washing. They usually contain a bundle of hollow fibers that provide a fluid path for blood. The space between the outer sides of the hollow fibers and the cartridge housing provides a second liquid path through which the treatment or washing liquid flows. The wall of the hollow fiber separates the fluid paths and allows an osmotic exchange of substances between blood and washing fluid. To produce such a dialysis filter cartridge, the bundle of hollow fibers is inserted into a housing and the ends of the housing are sealed using synthetic resin or a sealing compound. This step is complicated because the sealant must not get inside the hollow fibers and seal them, on the other hand, the housing or cartridge must be absolutely tight. For quality assurance, each individual filter cartridge must therefore be individually checked for permeability of the liquid paths and tightness, in accordance with the guidelines for quality assurance of the production processes and environment for medical products. The openness of the liquid paths and the tightness of the filter cartridges are tested with sterile water over a specified temperature range. After that, the wet dialysis filter cartridge must be dried. The filter cartridge is currently dried by blowing warm air through it, optionally supported by microwaves. This step is time-consuming and complex because moisture can collect in places that are less exposed to airflow. In addition, the dipole moment of the water molecules and the high surface tension of water make drying more difficult. The support of drying by microwaves is problematic because the microwave chambers have power-free areas, which is why food is usually heated on a turntable. In addition, the microwaves are reflected by the walls of the chamber and can penetrate each other wipe out Also, the seal of the filter cartridge or the sealing compound must not be damaged by the microwave, for example due to overheating.

[003] The filtration described in hemodialysis takes place osmotically (chemically) via several diaphragms or hollow fibers in the filter cartridge. In addition, there are also many purely physical (mechanical) membrane separation processes which separate according to the principle of mechanical size exclusion. All particles in the liquid that are larger than the membrane pores are held back by the membrane. The driving force behind this separation process is the differential pressure between the inlet and outlet of the filter surface, which is usually between 0.1 and 20 bar, and is therefore usually carried out in a sealed housing. Microfiltration (pore size > 0.1 microns) or ultrafiltration (pore size < 0.1 microns) is widely used in the beverage and pharmaceutical industries, but also in other areas where particle-free fluids (e.g. oil) are required. The candle filter usually consists of a filter housing and one or more candles inserted in it, through which the liquid flows from the outside to the inside. Closed single-use cartridge filters are common in the pharmaceutical industry, which have to be washed free of pyrogens and tested for leaks after manufacture for quality assurance. A typical design of the filter cartridges are wound cartridges, which are wound from a synthetic thread, e.g. from propylene, or a filter medium made from glass fiber, fleece, or a textile material. The advantages of such candle filters in a closed filter system are the low risk of contamination and no loss of fluid. The individual candle filters also have to be dried again after washing and testing, with the same problems to be overcome as with the dialysis filter cartridges. They are usually vacuum dried, which requires a considerable amount of equipment and time. The alternative use of warm, sterile air is comparatively energy-intensive and very expensive.

[004] Further relevant prior art for the production of dialysis filter cartridges is contained in DE 10 2007 035 583 A1, US 2012/0234 745 A1, US 5 556 591 A, JP H04-371 219 A. The prior art for production, Functional testing and drying of closed filter systems thus represents a problem.

BRIEF DESCRIPTION OF THE INVENTION

The problem is solved by a method for drying closed filter systems, especially after a functional test or a Washing comprising providing a chamber having a microwave antenna adapted to receive a filter module, wherein high and low microwave power zones are established in the chamber; providing means for generating microwaves of a discrete frequency in the range of 2.3 to 2.6 GHz in the chamber; the provision of a device which determines the reflected microwave power; the introduction of microwaves of a discrete frequency at which the highest power is converted in the liquid water, hereinafter also referred to as power loss; passing air or gas through the filter module so that evaporated water is removed from the system; and further determining and readjusting the microwave frequency at which the highest power is lost in the water (power dissipation) until the closed filter system is dry.

The method according to the invention is particularly suitable for closed filter systems and single-use filters which, because of their quality, have to be washed again after manufacture, or have to be checked individually for function and tightness for quality assurance. Typical examples of such filter systems are dialysis filters for blood washing or candle filters for the production of particle-free or pyrogen-free pharmaceutical liquids and drugs. In addition, there are many areas for closed filter systems with increased quality and safety requirements and, in particular, must not be damaged during or through drying after the functional test or washing.

In some embodiments of the method, the humidity of the gas emerging from the filter module or the filter system is also determined. In some embodiments of the method according to the invention, the chamber is also designed in such a way that areas of the filter with a bond or seal are in zones with low microwave power. This serves to protect the bonds from damage

In some preferred embodiments, the means for generating microwaves of a discrete frequency is a semiconductor microwave generator, i.e. a solid-state based microwave generator instead of a magnetron and electron tubes. In some embodiments, before the filter system is dried, the frequency spectrum from 2.3 to 2.6 GHz is examined to determine at which discrete frequency the absorbed microwave power is greatest—that is, the power converted in the water or the microwave energy introduced in the water hereinafter also referred to as power loss for short. This discrete frequency is then used as the starting value for drying. This frequency depends on the size of the filter, with the aforementioned spectrum being valid for filters with approx. 30 cm. Since the filter systems (closed candle filters and dialysis filter cartridges) contain adhesives and sealing materials, it is also important to pay attention to the discrete frequencies at which these materials absorb. Their absorption will usually be outside the range of the different states of the water in and on the fibers of the diaphragm or the filter material, i.e. outside the range of 2.3 to 2.6 GHz, but this should be checked and adjusted if necessary.

The device for drying closed filter systems such as filter cartridges and dialysis filters, according to the invention comprises a chamber for receiving a filter system such as a dialysis filter cartridge;

Devices for generating microwaves of a discrete frequency in the range from 2.3 to 2.6 GHz;

Devices for introducing microwaves into the chamber with the filter system;

Means for determining the reflected microwave power and the frequency at which the reflected power is lowest or the energy converted in the water is greatest, e.g. the S-parameter;

Devices for passing air or gas through the filter system.

The device for generating microwaves of a discrete frequency is preferably a semiconductor microwave generator. This can preferably also contain a device for determining the converted energy or the reflected power at a discrete frequency.

In some preferred embodiments, the device for drying filters also includes devices for feedback determination and tracking of the frequency to a frequency at which the reflected power is minimal and no other damage to the filter module occurs. The device for drying closed filter systems and dialysis filter cartridges is preferably designed in such a way that the chamber is divided into zones with high and low microwave power without contact. In some embodiments, the chamber is divided into high and low microwave power zones and is also designed so that once the closed filter system or the filter module, the areas with bonding or sealing come to rest in zones with low microwave power.

In some embodiments, the device for drying filter modules and dialysis filter cartridges can also have devices for determining the humidity in the exhaust air or in the exhaust gas. Furthermore, there can preferably be devices which determine the microwave energy absorbed in the chamber and optionally also the scattering parameters for the power input.

The use of the device is particularly helpful and preferred for dialysis filter cartridges, housings with filter cartridges, and other closed filter systems that are sealed with synthetic resin and/or adhesive. The advantage of frequency-guided microwave treatment is that the "free water" in the center of the filter cartridge or filter module is first evaporated with the frequency starting value, then the water bound to the various surfaces is heated and evaporated and finally, via the frequency shift, the water that has accumulated in remote corners and niches of the filter housing. The frequency control also changes the wave pattern in the chamber and in a way looks for all free water in the housing or the module. Although the areas with adhesive bonds and seals also contain water, according to the invention these are in areas or zones with lower microwave radiation. These ranges are reached, but only with a fraction of the power compared to conventional microwave processes. In addition, the heated gas that is passed through - usually dehumidified sterile compressed air - dries the areas with bonds and seals. The method according to the invention and the use of the device described with frequency-controlled microwave power thus dries closed filter systems such as dialysis filter cartridges and candle filters much more gently than before, so that the failure rate is lower. This advantage is striking. FIGS. 3 and 4 show the change in the resonant frequency and the effective power introduced as a function of the frequency adjustment for a dialysis filter cartridge, the curves showing the different states of drying.

BRIEF DESCRIPTION OF ILLUSTRATIONS

It shows: 1 shows a representation of a dialysis filter cartridge and the power introduced by microwaves in the water in the wet filter when using the resonant frequency;

Fig. 2 is an illustration of a dialysis filter cartridge and the power introduced by microwaves in the water in the dry filter at resonant frequency, with the mid-range microwave power being absorbed by the wet fibers;

3 shows diagrams (A) of the course of the resonant frequency and (B) of the applied effective power in watts with the frequency adjustment over time;

4 shows a diagram with the time course of the input (absorbed) power in percent and the reflected power in percent together with the percentage of air humidity in the sight glass and the measured air temperature of the outflow in degrees Celsius;

5 is a front view (cutaway) of the microwave chamber: (A) with and (B) without the dialysis filter cartridge inserted, the sealed ends of the cartridge being partially protected from microwave power; (C) rear view of the microwave chamber with connection to the microwave generator, (D) sectional view of the microwave chamber with microwave antenna;

6 shows a detailed view of the compressed air connection to the dialysis filter cartridge in the microwave chamber;

Fig. 7 shows a diagram of the scattering parameters S1,1 of the chamber (largest version of type A) with an inserted wet dialysis filter cartridge (start of the process) over the frequency band (2.3 - 2.6 GHz) or the frequency band used (2.4 - 2 .5 GHz);

8 shows a diagram of the scattering parameters S 1 ,1 of the chamber of type A with a dry dialysis filter cartridge or at the end of the process;

9 shows a diagram of the scattering parameters S1,1 of the chamber with a wet dialysis filter cartridge of the smallest type B (start of the process) over the frequency band (2.3-2.6 GHz) or the frequency band used;

10 shows a diagram of the scattering parameters S1,1 of the type B chamber with a dry dialysis filter cartridge (at the end of the process);

11 shows the distribution of the power dissipated in the water in the respective filters of type A (largest version) at different resonance frequencies;

12 shows the distribution of the power converted in the water in the respective filters of type B (smallest version) at different resonance frequencies; Fig. 13 Graphs comparing S-parameters for a type B (smallest design) and type A (largest design) filter.

DETAILED DESCRIPTION OF THE INVENTION

According to the invention, a microwave chamber is provided which has a resonant frequency at the lower limit of the relevant frequency band (2.3 to 2.6 GHz) when a closed filter module is used, such as a dialysis filter cartridge or a candle filter when wet. In the cases shown, the relevant frequency band is between 2.4 and 2.5 GHz, corresponding to medium-sized filter modules with a diameter of 10 to 30 cm. In the case of very large or very small filter modules, correspondingly higher or lower frequency bands are suitable. In the following, the device and the method are described by way of example for filter systems with a hollow fiber module. However, the device and the method are equally suitable for modules with candle filters and other membrane filters.

The aforementioned resonant frequency stands for the frequency at which the power reflection of the chamber is minimal and the power consumption takes place in the water; see FIG. 1. It is taken into account that the filters or the filter modules can have different diameters and therefore also contain different amounts of water. The chamber is selected in such a way that the largest filter unit, the largest filter module, the largest filter cartridge, which contains the most water and thus has the lowest resonance frequency in the chamber, is still within a usable frequency band of 2.4 GHz - 2.5 GHz , i.e. just above 2.4 GHz

[0018] At the start of drying, the resonant frequency of the wet filter is determined by the equipment or the microwave generator, preferably in a scan run, and the determined resonant frequency for drying is taken as the starting value for the microwave. This preliminary step can be omitted and is optional if the filter modules are manufactured with very tight tolerances and a constant frequency start value can be used for the microwave generator. Nevertheless, the determination of the starting parameters can represent an optimization of the method.

If the starting value for the microwave is fixed, the microwave generator begins to deliver power at this frequency into the chamber. At the same time, it is continuously determined whether and how the resonant frequency changes, because water will evaporate due to the absorbed microwave power and will be discharged from the filter module, the filter cartridge, by the air flow that is applied at the same time. the The use of a warm through-air flow allows drying to take place more quickly, but is not absolutely necessary and very energy-consuming. Sterile warm clean air is very expensive and complex to produce. With a reduction in the amount of water in the filter module or the dialysis filter cartridge, the resonant frequency increases. According to the invention, this change in the resonance is detected by the equipment, for example using the microwave reflection, and the emitted microwave frequency is tracked or increased accordingly. The generator follows the change in frequency by adapting the frequency to the absorbed power. This minimizes reflected power and maximizes power input into the water.

The microwave generator follows the resonant frequency change by adjusting the frequency of the power delivered so that the absorbed power is maximum; see Figure 3. In this way, the reflected power is minimized and the power input into the water is maximized. The change in frequency stagnates at a point since most of the water has been discharged (see FIG. 3, after approx. 460 seconds). There is then only water in appreciable amounts in the shielded areas with the sealing material or in the bonding of the filter module (filter cartridge, candle filter, disposable filter)

The further use of microwaves is now, for lack of water in the filter or in the bundle of hollow fibers, the sealing and adhesive mass and the water it contains is heated. For the same filter in the dry version, the chamber shows the picture shown in FIG. The chamber is selected in such a way that the resonances at which the microwave power couples significantly into the areas of the filter to be protected are outside the ISM band of 2.4 to 2.5 GHz and therefore cannot be inadvertently hit by the generators (see Fig. 11 for type A dry dialysis filter cartridges - largest version). The middle image shows the rest of the resonance with coupling into the middle range. This is the mode illustrated in the latter half of the power versus time diagram of Figure 3B. The implementation of the filter in the simulation can deviate minimally from the real filter. But the principle remains untouched. The middle image shows that some power couples into the sealing and bonding areas to be protected when the water is pushed out of the middle area. However, this power is not very high due to the low adjustment of less than -1dB, since the microwave generator automatically regulates its output power. In addition, the power ratio between the central area and the ends differs by more than a factor of 2, so that this is tolerated by the splices, and moisture removal from the splices is also accelerated. through further shielding only a small part of the power reaches this area. The use of warm air significantly shortens the final drying step as it drives the remaining water out of the shielded seal very efficiently. The process ends as soon as the measured humidity in the exhaust air falls below a target value; see figure 4.

The chamber is designed or designed in such a way that the resonance of the chamber when power is input into the water in a type A filter (largest version) when wet is still within the usable frequency band, and that the resonance of the chamber when power is input in the areas to be protected with a type B filter (smallest version) - i.e. in the areas with the adhesive and sealing compound - is outside the usable frequency band when dry.

The method is specially developed for the drying of filters with a focus on dialysis filters and candle filters. Because of the variable microwave frequency emitted, the process requires that the microwaves be generated by semiconductors or solid-state technology. Magnetrons can only generate and emit microwaves of a fixed specific frequency or a chaotic frequency. A controllable drying process can be achieved according to the invention through the use of solid-state microwave generators, which allow a very precise setting of power and frequency. The entire drying process can be achieved entirely by microwaves without additional drying by hot air. Power adjustment is not possible with conventional magnetron-based microwave technology.

The drying application can have a modular structure, so that the application is scalable in parallel and individually adaptable. The filter modules (dialysis filter and candle filter cartridges) can be inserted into the drying chambers manually or fully automatically using a robot, as is currently the case.

A microwave chamber with non-contact separation of the zones corresponding to the functionally different areas of the filter cartridges and modules is presented. The drying chamber offers the advantage that it can be equipped with filter cartridges to be dried via a door. The person skilled in the art recognizes that the assembly can be carried out from the front, from behind, from the side or also from above or below. A chamber which allows the use of robots for equipping the drying chamber is preferred. The separation of the zones corresponds to the areas with high and low power absorption. After a leak test, dialysis filter cartridges contain a particularly large amount of water in the area of the bundle of hollow fibers. On the other hand, the areas with the synthetic resin or the sealing compound must be protected from excessive microwave power. Similarly with closed housings with candle filters. Furthermore, the chamber requires a connection for discharging the water. The power introduced by the microwave generator and converted in the water occurs primarily in the central area of the filter, where most of the water is present. Due to the design and the non-contact separation of the zones, protective caps for the areas to be protected on the filter modules are no longer required. This increases the reproducibility of drying and makes the drying process considerably easier. Microwave drying is made even safer by the fact that the resonances with losses in the zones to be protected are outside the ISM band. Furthermore, the fact that the resonance of the chamber changes due to the loss of water is used. This fact, and by measuring and tracking the resonance, one can introduce microwave power into the water at low reflection. The water is also bound differently in the filter material or on the fibers of a dialysis filter cartridge: as "free" water or absorbed on a surface. These different states cause different resonance frequencies or peaks in the curve with the resonance frequency. The use of a gas, preferably compressed air, to discharge the evaporated water accelerates the drying process. This actively dries the microwave-sensitive areas with sealing and adhesive mass.

A device for drying closed filter systems with a hollow fiber or candle filter module has been described, comprising a microwave chamber that can be equipped with a filter cartridge or a filter module. The microwave chamber distinguishes itself by dividing zones of high and low microwave absorption without contact. The zone with high absorbed power corresponds to the central area of the filter module, where the bundle of hollow fibers or the filter material is located. The zones with low microwave absorption correspond to the end areas of the filter cartridge, which are more sensitive to microwaves, where there are further seals and adhesives. To dry the wet filter module, the microwave frequency with the highest absorbed power is first determined, then microwave power is introduced at this frequency, and while the filter module is drying, the reflected microwave power is continuously determined by the equipment and kept as low as possible by tracking the microwave frequency. The water is also discharged from the filter with a stream of air or gas. The process requires a generator whose frequency can be adjusted - in practice a microwave generator on solid state technology. It then allows quick and gentle drying. In particular, rejects due to accidental overheating of temperature-sensitive areas of the filter system and at the seals and bonds are avoided.

REFERENCE LIST

10 dialysis filter cartridge

12 compressed air connection (supply and exhaust air)

14 Filter cartridge connection (blood, washing liquid)

16 gasket, bonding

52 areas of low microwave power in the microwave band used

54 antenna with external connection

56 Microwave Chamber

58 Low Microwave Exposure Zone

62 External cartridge connection

64 Vertically moveable compressed air connection (above) for fixing the filter cartridge and sealed against cold and warm compressed air;

66 Lateral compressed air connection for cold and warm compressed air, including seal, and for aligning/centering the filter cartridge;

72 Resonance of Type A wet filter chamber (largest version)

74 Usable Frequency Band

76 Resonance of Type B Wet Filter Chamber (Smallest Version)

82 Resonance of chamber with type A dry filter

84 Usable Frequency Band

86 Resonance of chamber with type B dry filter

Claims

PATENT CLAIMS

1. A method for drying closed filter systems, in particular after washing or a functional test, characterized by

providing a microwave antenna chamber adapted to receive a filter module, wherein high and low microwave power zones are established in the chamber;

providing means for generating microwaves of a discrete frequency in the range of 2.3 to 2.6 GHz in the chamber;

providing a device which determines the reflected microwave power;

introducing microwaves of a discrete frequency at which the highest absorption of power occurs;

passing air or gas through the filter so that evaporated water is discharged from the housing; Further determination and readjustment of the microwave frequency at which the highest energy input into the existing water takes place until the filter module is dry.

2. The method according to claim 1, wherein the humidity of the gas emerging from the filter module is determined.

3. The method according to claim 1 or 2, wherein the chamber is designed such that areas of the filter module with a bond or seal are in zones with low microwave power.

4. The method according to any one of claims 1 to 3, wherein the means for generating microwaves of a discrete frequency is a semiconductor microwave generator.

5. The method according to any one of claims 1 to 4, wherein the frequency spectrum from 2.3 to 2.6 GHz is examined to determine at which discrete frequency the microwave power absorbed by the water is greatest.

6. The method according to any one of claims 1 to 5, wherein the closed filter system is selected from hollow fiber modules for plasmapheresis and blood washing, candle filters for particle and sterile filtration, disposable filter modules.

7. Device for drying closed filter systems, characterized by a chamber for accommodating a filter module; means for generating microwaves of a discrete frequency im 2.3 to 2.6 GHz range; means for introducing microwaves into the chamber with the filter module;

means for determining the reflected microwave power and the frequency at which the reflected power is lowest; and

Means for passing air or gas through the filter module. Device for drying according to claim 7, comprising means for feedback determination and tracking of the frequency to a frequency at which the reflected power is minimal. Apparatus according to claim 7 or 8, wherein the chamber is non-contact divided into high and low microwave power zones. Apparatus according to any one of claims 7 to 9, wherein the chamber is divided into high and low microwave power zones and designed such that after the filter module is inserted the areas of bonding or sealing are in low microwave power zones. Device according to one of the preceding claims, comprising devices for determining the humidity of the exhaust air or the exhaust gas. Apparatus according to any one of the preceding claims, wherein the means for generating microwaves of a discrete frequency is a semiconductor microwave generator. Apparatus according to claim 12, wherein the means for generating microwaves of a discrete frequency includes integrated means for determining absorbed power or reflected power at a discrete frequency. Apparatus according to claim 13, wherein the microwave energy absorbed in the chamber is determined by a scattering parameter. Use of the device according to one of Claims 7 to 14 for drying filter modules which are sealed with synthetic resin and/or adhesive.