DE102020208024A1 - Waterproof pressure sensors with a biocidal surface and a manufacturing process - Google Patents

Abstract

The present invention claims a manufacturing method for a waterproof pressure sensor with increased robustness against mechanical layers acting on the pressure transmission, caused by aging of biological substances or growth by microorganisms, and a waterproof pressure sensor with these properties according to this manufacturing method. In this case, the sensor has a sensor element which is at least partially covered, directly or indirectly, with a potting compound. The essence of the invention is that the potting compound, for example a gel, contains a biocide or a layer is applied to the potting compound that contains a biocide. The potting compound can also be designed in such a way that it has a first layer with an increased proportion of biocide in a direction that is preferably assigned to the environment, while no or only a small proportion of biocide is present in a second layer assigned to the sensor element below is. Furthermore, the potting compound can also be equipped without a biocide if a component spatially adjacent to the potting compound has biocidal properties.

Description

The invention relates to waterproof pressure sensors with a biocidal surface and a corresponding production for these sensors.

State of the art

Sensors, especially micromechanical sensors, especially waterproof pressure sensors, are increasingly used in every area of life. These sensors are often exposed to environmental conditions in which microorganisms such as fungi and bacteria can thrive due to their low nutrient requirements. Dust and residues of various materials on the surface of sensors can be sufficient to promote growth, even if the actual substrate does not provide a breeding ground for the microorganisms.

For sensors such as waterproof pressure sensors that are used in direct contact with the environment, potting compounds are used, e.g. made of elastic gels, to protect the sensor element of the sensors. If these sensors are used in applications that require body contact, e.g. in smartphones, fitness trackers or smartwatches, optimal conditions can be created through contact with sweat, care products, fibers or flakes of skin, so that bacteria, fungi or algae can settle on the potting compound and can spread. This settlement or, in the most extreme case, the complete covering of the potting compound including a possible fixation in the edge area with neighboring components of the sensor packaging can lead to the ambient pressure not being able to be passed on to the sensor element, or only being falsified. Removal of this covering is often not possible or endangers the integrity of the sensor.

It is already known to provide surfaces with a large number of substances in order to prevent or at least hinder the settlement of microorganisms, for example from the publication “Antimicrobial coatings on textiles modification of sol gel layers with organic and inorganic biocides”, Mahltig et al ., J Sol-Gel Sci Technol (2010). It is known to equip items of clothing with silver particles in order to prevent the colonization of bacteria.

In addition, from the DE 10 2015 204 499 A1 also known to introduce silver particles into the gel of a pressure sensor in order to protect the pressure sensor element from external influences. From scripture DE 10 2011 078 937 A1 the use of copper or gold grains in the gel of a pressure sensor is known. The use of biocide layers in a layer material is from the text EP 1790224 B1 known.

Disclosure of the invention

The present invention claims a manufacturing method for a waterproof pressure sensor and a waterproof pressure sensor according to this manufacturing method. In this case, the sensor has a sensor element which is at least partially covered, directly or indirectly, with a potting compound. The essence of the invention is that the potting compound, for example a gel, contains a biocide or a layer is applied to the potting compound that contains a biocide without significantly changing the properties of the gel (e.g. electrical conductivity), but at the same time to prevent or limit the formation of a layer on the gel surface in such a way that the mechanical properties do not change, in particular a mechanically more stable connection extending beyond the gel (eg with a gel-holding coating). The potting compound can also be designed in such a way that it has a first layer with an increased proportion of biocide in a direction that is preferably assigned to the surroundings, while a second layer underneath, assigned to the sensor element, has no or only a small proportion of biocide. Biocidal doping or coating of a component that is spatially close to the gel can also be considered as a solution option if it positively supports the facts described above.

The advantage of the invention is that colonization of potting or gelling compound or its surface caused by microorganisms by microorganisms such as bacteria, fungi or algae is prevented or their growth is delayed. This prevents the formation of a layer e.g. through a biofilm or the formation of a network of fungal mycelium on the gel surface, and also prevents the formation of a layer beyond the gel surface. As a result, an impairment of the pressure transmission caused by microorganisms cannot take place. This makes the sensors more robust, especially in applications in contact with media, in high humidity and in the event of contamination by nutrients in the form of sweat or dust.

The biocide can be introduced into the potting compound before the potting compound is applied to the sensor element. In this way, for example, a homogeneous distribution can be achieved. Alternatively, the biocide can also concentrate in the lower or upper area during the drying phase of the casting compound. It is also possible to apply the biocide only after it has been applied to introduce the potting compound on the sensor element into the potting compound or to apply it to the surface of the potting compound by means of a separate layer formation. Alternatively, a component that is spatially close to the gel can also have biocidal properties that positively support the above-mentioned goal.

To prevent the colonization of surfaces with microorganisms, various organic, inorganic or organometallic biocidal active substances are used. Examples of organic biocides are triclosan, isothiazolinones or zinc pyrithions. Metal salts (e.g. NaN3, AgN03, CuS04) are used as inorganic biocides. In addition to their compounds, copper, zinc or silver are also used in metallic form. Metallic silver in particular is used as a biocide in a wide variety of applications, including in polymers. Due to their high specific surface, nanoparticles have a particularly strong antimicrobial effect.

The antimicrobial properties of silver are based on the reaction of monovalent silver ions (Ag +) with cell components of microorganisms. Silver ions are passively and actively transported into cells as positively charged ions. A silver ion concentration of 10-9 - 10-6 mol / L is antimicrobial. Silver acts on several levels. Silver ions suppress the proton motor force, the respiratory chain and the membrane permeability of cell membranes, which can lead to cell death. Silver is bound to the cell walls and membranes of microorganisms. Gram-negative bacteria, which play a particularly important role in biocontamination in water and the primary adhesion of biofilms, are more sensitive to silver ions than gram-positive bacteria due to the structure of their cell wall. Intracellularly, Ag + acts in the reaction with proteins / enzymes and the subsequent denaturation. Silver ions react with thiol groups (-SH) in proteins, interrupt the metabolism and thus lead to cell death. The exposure time required to inactivate microorganisms is species-specific.

Compared to other heavy metals with antimicrobial activity, such as zinc (Zn2 +) or copper (Cu2 +), Ag + is significantly more reactive and, for this reason, has the strongest effect on microorganisms. Basically, copper and zinc, like other metals, are suitable for reducing biological contamination.

If the sensor is manufactured using micromechanical processes, the potting compound or the biocide can also be applied using micromechanical processes.

Further advantages emerge from the following description of exemplary embodiments or from the dependent claims.

Embodiments of the invention

The biocide (on an organic, inorganic or metallic basis) is introduced into the sensor potting compound or applied to the potting compound or alternatively introduced into a component spatially close to the gel or applied to a component spatially close to the gel. In order to achieve a large surface, nanoparticles can be used that are finely distributed in the gel or in the spatially close component. Furthermore, it is advantageous if a homogeneous distribution of the biocide develops, in particular in the area in contact with media.

In the case of metal-based biocides, metal ions are released from the metal at the interfaces and are effective there. Metal ions penetrate the cell through passive and active transport and can lead to oxidative stress. Proteins that are necessary to maintain metabolism are denatured, which can lead to cell death. Organic and inorganic biocides intervene directly in the metabolism of the microorganisms.

The colonization of the gel surface by microorganisms is prevented. By introducing the biocide into or on the gel, the protective agent is not washed out and can prevent microbial infestation in the long term. This protection prevents a mechanically stable layer formation, which in turn influences the pressure transmission of the gel or the system.

QUOTES INCLUDED IN THE DESCRIPTION

This list of the documents listed by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent literature cited

• DE 102015204499 A1 [0005]
• DE 102011078937 A1 [0005]
• EP 1790224 B1 [0005]

Claims (12)

Process for the production of a watertight pressure sensor with increased robustness against the formation of mechanically stable layers, which impair the pressure transmission to the sensor element and result from a biological change of environmental substances (e.g. sweat, food, etc.) or from growth with microorganisms, whereby for production • is applied directly or indirectly with a potting compound on a sensor element of the sensor, characterized in that • a biocide is introduced into the potting compound. Procedure according to Claim 1 , characterized in that the biocide is introduced into the potting compound before application. Method for producing a sensor, wherein for production • a sensor element of the sensor is covered directly or indirectly with a potting compound, characterized in that • a biocide is applied to the potting compound. Procedure according to Claim 1 , characterized in that the biocide is part of one of the components spatially adjacent to the gel. Method according to one of the preceding claims, characterized in that the biocide has an organic, inorganic or metallic base. Method according to one of the preceding claims, characterized in that the biocide has nanoparticles. Method according to one of the preceding claims, characterized in that the biocide is distributed homogeneously in the casting compound. Method according to one of the preceding claims, characterized in that the sensor is produced by means of micromechanical processes. Method according to one of the preceding claims, characterized in that the biocide has triclosan, isothiazolinones or zinc pyrithions, silver, copper, zinc or metal salts, in particular NaN3, AgN03, CuS04. Sensor device produced by a method of Claims 1 to 9 , the sensor device having • a sensor element and • a potting compound directly or indirectly on the sensor element, characterized in that the potting compound includes a biocide. Sensor device produced by a method of Claims 1 to 9 wherein the sensor device has • a sensor element and • a potting compound directly or indirectly on the sensor element, characterized in that a biocide is applied to the potting compound. Sensor device produced by a method of Claims 1 to 9 wherein the sensor device • has a sensor element and • a potting compound directly or indirectly on the sensor element, • a component spatially adjacent to the potting compound, which is characterized in that it has biocidal properties.