• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to a sensor arrangement (1) for determining and optionally measuring a concentration of a plurality of gases, comprising a sensor structure (2) with conductive elements arranged in a matrix (3) and a multiplicity of contacts (4), the conductive elements being connected to the Contacts (4) are connected, wherein the conductive elements are formed with different metals and / or metal oxides in order to measure in a gas mixture more than two gases isolated from each other. Furthermore, the invention relates to a use of such a sensor arrangement (1). Furthermore, the invention relates to a method for producing a sensor arrangement (1) for determining and optionally measuring a concentration of a plurality of gases.
    公开号:AT519492A1
    申请号:T51174/2016
    申请日:2016-12-22
    公开日:2018-07-15
    发明作者:
    申请人:Mat Center Leoben Forschung Gmbh;
    IPC主号:
    专利说明:

    Summary
    The invention relates to a sensor arrangement (1) for determining and possibly measuring a concentration of several gases, comprising a sensor structure (2) with conductive elements arranged in a matrix (3) and a plurality of contacts (4), the conductive elements with the Contacts (4) are connected, the conductive elements being formed with different metals and / or metal oxides in order to measure more than two gases in isolation from one another in a gas mixture.
    The invention further relates to the use of such a sensor arrangement (1).
    The invention further relates to a method for producing a sensor arrangement (1) for determining and optionally measuring a concentration of several gases.
    Fig. 3/29
    Sensor arrangement for determining and possibly measuring a concentration of several gases and method for
    Production of a sensor arrangement
    The invention relates to a sensor arrangement for determining and optionally measuring a concentration of a plurality of gases, comprising a sensor structure with conductive elements arranged in a matrix and a large number of contacts, the conductive elements being connected to the contacts.
    Furthermore, the invention relates to the use of such a sensor arrangement.
    The invention further relates to a method for producing a sensor arrangement for determining and optionally measuring a concentration of several gases.
    Gas sensors are known from the prior art and are designed for the detection of gaseous substances. Metal oxide sensors are used in particular for measuring gases. These are used, for example, to detect carbon monoxide. A disadvantage of such sensors known from the prior art, however, is that they either react to several gases or cannot distinguish between two or more types of gas.
    US 2011/0120866 A1 discloses a gas sensor which is designed to detect two gases at the same time. However, even with such a gas sensor, it is not possible to measure more than two types of gas isolated from one another.
    EP 0 527 258 A1 discloses a gas sensor array for detecting individual gas components in a gas mixture. However, such a gas sensor array cannot be configured so flexibly that two or more gases can be determined simultaneously, since a gas can only be determined by calculations from sensor signals.
    This is where the invention comes in. The object of the invention is to provide a sensor arrangement of the type mentioned at the outset which can be configured flexibly.
    Another aim is to specify the use of such a sensor arrangement.
    / 29
    It is also an aim to specify a method of the type mentioned at the outset with which a flexibly configurable sensor arrangement can be produced.
    The object is achieved in that, in a sensor arrangement of the type mentioned at the outset, the conductive elements are formed with different metals and / or metal oxides in order to measure more than two gases in isolation from one another in a gas mixture.
    An advantage achieved with the invention can be seen in particular in that the sensor structure, in particular the conductive elements arranged in a matrix or formed as a matrix, creates a flexibly configurable sensor arrangement with which two or more gases of a gas mixture can be detected or are measurable. The conductive elements are at least partially formed from at least two different metals and / or metal oxides. In a sensor arrangement according to the invention, the individual conductive elements made of different metals and / or metal oxides are arranged or interconnected in the matrix in such a way that they can be coupled to one another externally via the contacts and interconnected in order to individually determine two or more different gases and moreover, if necessary, measure a concentration of the individual gases. Each contact is connected to at least one conductive element in order to subsequently be able to determine the presence of a gas. By forming the sensor arrangement from different metals and / or metal oxides, the sensor arrangement forms a plurality of sensors which can be coupled to one another and which can be individually controlled via the contacts and interconnected with one another. The sensors are arranged in particular at points of contact between two or more conductive elements. In addition, the sensors are arranged at a distance from one another.
    In particular, the sensor structure or the conductive elements are formed from or with two different metals and / or metal oxides, preferably from copper oxide and / or zinc oxide and / or tin oxide. The sensor structure includes, for example, a matrix of strands made of different metals and / or metal oxides arranged in a grid. It is advantageous here if the strands are arranged approximately perpendicular to one another and are formed from different metals and / or metal oxides. The strands run one above the other at crossing points and can be at these / 29
    Crossing points can be connected to one another, the crossing points being arranged at a distance from one another. Such a vertical arrangement of two different metals and / or metal oxides can, for example, form a p-n transition. The strands can also advantageously be formed from layers and / or nanofibers. In addition, different contact elements can also be arranged in matrix form on a substrate, wherein these can also be partially or completely converted into different metal oxides and are connected to one another in the form of a grid.
    It is favorable if the matrix comprises metal films and / or metal oxide films. The metal films and / or metal oxide films are in particular in the form of strips and are arranged in a grid or matrix form on a substrate. Contacts are arranged at respective ends of the strip-shaped metal films and / or metal oxide films, by means of which contacts can be actuated via sensors of different designs and spaced apart from one another. Sensors are formed on or between intersection points of the metal films and / or metal oxide films, the intersection points being arranged at a distance from one another. In particular, the metal films can subsequently be oxidized to metal oxide films and / or metal oxide nanofibers, as a result of which metal films become gas-sensitive metal oxides. It is expedient if each row or column of the metal films can be converted into a different metal oxide, for example by thermal oxidation. It can further be provided that the metal films and / or metal oxide films are designed as bundles of nanofibers.
    It is advantageous if the sensor structure comprises nanofibers. The nanofibers are arranged on or between conductive elements of the metal matrix, the nanofibers being transferred to a substrate via a transfer process, for example thermally oxidized thereon. The nanofibers are preferably made of metal oxides and gas-sensitive, for example by their electrical conductivity, which further increases the sensitivity of the sensor arrangement. The nanofibers can also be produced by oxidation of suitable metal films on a metal grid.
    It is particularly preferred if contact elements, in particular metallic and / or metal oxide contact elements, are provided, the nanofibers being arranged between the contact elements. In each case, two nanofibers are advantageously oriented relative to one another such that the second nanofiber is oriented at an angle between 45 ° and 135 °, particularly preferably approximately perpendicular to the first nanofiber. The contact elements connected to the nanofibers thereby form a grid, wherein bundles of nanofibers are preferably provided. The contact elements are advantageously of approximately rectangular, in particular square, design and arranged in a matrix on a substrate. The outer contact elements of the matrix thus formed are each connected to a contact. The contact elements can grow directly on a substrate or can be vapor-deposited thereon. It can be provided that the contact elements and / or the nanofibers are formed from different metals and / or metal oxides.
    It is advantageous if the nanofibers are doped. Foreign atoms are introduced into the respective nanofibers made of a metal and / or metal oxide in order to make them sensitive to different gases or differently sensitive.
    It is furthermore expedient if the sensor structure comprises nanoparticles in order to sensitize sensors differently. The sensor structure can thus be functionalized in different ways. The nanoparticles can be used to assign different properties and / or sensitivities to the sensors formed in the sensor structure, as a result of which subsequently two or more gases in a gas mixture can be reliably measured in isolation from one another or individually. This opens up another parameter space for adapting sensitivities to specific gases. The nanoparticles can be printed in particular on the matrix of the sensor structure. The different conductive elements of the sensor structure or the matrix are preferably doped with different or different nanoparticles. However, the same nanoparticles can also be provided.
    It is advantageous if the conductive elements arranged in the matrix are formed at least partially from tin oxide and / or zinc oxide and at least partially from copper oxide, the tin oxide and / or zinc oxide being n-doped and the copper oxide p-doped, for example. As a result, electron donors are implanted in the tin oxide and / or zinc oxide and electron acceptors in the copper oxide. Intrinsic doping of the metal oxide can be reversed by additional doping. The conductive elements can also be formed at least partially from another metal oxide. The conductive elements arranged in the matrix include, for example, metal films and / or / 29
    Metal oxide films made from different metal oxides. Alternatively, the conductive elements can comprise contact elements made of different metals and / or metal oxides, which are connected to one another via, for example, nanofibers. Furthermore, the conductive elements can also comprise nanofibers, which are arranged in a lattice shape with respect to one another. The matrix of doped tin oxide and / or zinc oxide and doped copper oxide or the conductive elements arranged in the matrix can be connected to one another, as a result of which a diode is formed. In addition to the possibility of coupling individual sensors with one another and interconnecting them, this also has the effect that current can pass through unhindered and is blocked in the other direction.
    In the case of the sensor arrangement, the matrix comprising metal films and / or metal oxide films, a transition between regions with different doping is expediently formed at a crossing point between approximately perpendicularly arranged metal films. A p-n transition or an n-p transition can be formed. An n-p-n junction or a p-n-p junction can also be generated by a matrix connection, as a result of which a transistor is formed. Different transitions between areas with different doping can thus be activated. The metal films are formed as strands with different metal oxides or bundle-shaped nanofibers with different metal oxides or converted into metal oxide films, the metal oxide films being doped differently.
    It is also advantageous if the sensor arrangement can be configured flexibly. The sensor arrangement forms a plurality of spaced-apart sensors, each sensor advantageously being sensitized or reacting to a different gas. Depending on how the individual contacts are tapped, different gases can be identified and measured. A flexible and individually configurable sensor arrangement can be used, for example, as a smart sensor. This can be used in particular in building control or in the control of an air conditioning system.
    In order to be able to sensitize the sensor arrangement in addition to measuring certain gases, it is advantageous if the sensor arrangement comprises a heating device and / or a cooling device in order to bring the sensor arrangement to a defined temperature or to subject it to defined temperature cycles.
    / 29
    A sensor arrangement according to the invention is advantageously used for the simultaneous determination of different gases.
    The further goal is achieved if a method of the type mentioned at the beginning comprises the following steps:
    Provision of a substrate,
    - Applying a sensor structure made of different metals and / or metal oxides comprising conductive elements arranged in a matrix and a large number of contacts on the substrate and
    - Functionalization of sensors formed in the sensor structure.
    An advantage achieved in this way can be seen in particular in the fact that the combination of the application of the sensor structure with conductive elements arranged in a matrix and several contacts and the functionalization of the sensor structure allows a sensor arrangement to be produced for the isolated measurement of two or more gases in a gas mixture. In a sensor arrangement produced by the method according to the invention, individual, spaced-apart sensors in a matrix can be coupled to one another in such a way that they can be controlled and connected to one another externally as desired. In particular, different types of sensors can be coupled to one another and interconnected, so that more than two different gases can be recognized and measured individually in a gas mixture.
    The sensor structure or the matrix is formed from different metals and / or metal oxides, for example from copper oxide and / or zinc oxide and / or tin oxide. In particular, the sensor structure is formed from strands arranged from a grid of different metals and / or metal oxides. It is advantageous here if the strands are arranged approximately perpendicular to one another. It is also advantageous if the strands are made from different metal oxides. The strands can advantageously also be formed from nanofibers. In addition, contact elements can also be arranged in matrix form on the substrate. It is advantageous if these are formed from different metal oxides and are connected to one another in a lattice shape.
    / 29
    It can also be advantageous if the sensor structure is formed from n-doped tin oxide and / or zinc oxide and from p-doped copper oxide. For this, electron donors are implanted in the tin oxide and / or zinc oxide and electron acceptors in the copper oxide. The matrix of the sensor structure includes, for example, metal films and / or metal oxide films made of different metals and / or metal oxides. The matrix or elements of, for example, doped zinc oxide and / or tin oxide and doped copper oxide of the matrix can be connected to one another or to one another, as a result of which a diode is formed. In addition to the possibility of coupling individual sensors with one another and interconnecting them, this also has the effect that current can pass through unhindered and is blocked in the other direction.
    It is advantageous if the sensor structure is functionalized with nanoparticles. Functionalization can be carried out by sensitization, the nanoparticles being applied in particular to the matrix of the sensor structure, in particular printed on, for example using an inkjet printer. The sensor structure can thus be functionalized in different ways. Different properties and / or sensitivities are assigned to the sensors formed by the nanoparticles, as a result of which two or more gases can subsequently be reliably measured in isolation from one another. This opens up another parameter space for adapting sensitivities to specific gases. Different elements of the sensor structure or the matrix are preferably sensitized or doped with different nanoparticles. However, only a single type of nanoparticle can be used to sensitize the sensor structure.
    Functionalization can also be carried out using classic doping. In addition to classic doping, other foreign atoms or nanoparticles, for example noble metals such as palladium, platinum, etc., can alternatively or additionally be embedded or applied in elements of the sensor structure in order to make them sensitive to different gases.
    It is advantageous if nanofibers are oxidized onto the substrate between contact elements arranged in the matrix, in particular metallic and / or metal oxide contact elements. The contact elements either grow directly on the / 29
    Substrate or are applied to the substrate, for example by vapor deposition. The nanofibers are thermally oxidized onto the substrate approximately perpendicular to one another between the contact elements. A grid is formed by the contact elements connected to the nanofibers, bundles of nanofibers being provided. The contact elements are advantageously of approximately rectangular, in particular square, design and arranged in a matrix on a substrate. The outer contact elements of the matrix thus formed are each connected to a contact. Alternatively, the nanofibers can also be printed on the substrate.
    It can be advantageous if metal films and / or metal oxide films are evaporated onto the substrate. The metal films and / or metal oxide films are in particular formed in strips and are vapor-deposited onto the substrate in the form of a grid or matrix. Contacts are arranged at respective ends of the strip-shaped metal films, by means of which sensors of different designs can be controlled. Sensors are formed at and / or between intersection points of the conductive elements, the intersection points being arranged at a distance from one another on the sensor structure. It is expedient if the conductive elements of a row or column are at least partially formed from different metal oxides. It can also be expedient if the metal films and / or metal oxide films are designed as bundles of nanofibers.
    Further features, advantages and effects result from the exemplary embodiments presented below. In the drawings, to which reference is made, show:
    1a shows a sensor arrangement;
    1b shows a schematic representation of an interconnection of two contacts;
    2 shows a sensor arrangement according to the invention;
    3 shows a further sensor arrangement according to the invention;
    4 shows a further sensor arrangement according to the invention;
    5 shows an image of contact elements;
    6 shows a further image of contact elements;
    7 shows a further image of contact elements;
    / 29
    8 shows a further image of contact elements;
    9 shows an image of a two-dimensional connection of contact elements.
    FIG. 1 a shows a sensor structure 2 for a sensor arrangement 1 according to the invention. The sensor structure 2 comprises conductive elements arranged in a matrix 3 and a plurality of contacts 4, which are formed, for example, from silver or titanium. In FIG. 1 a, the matrix 3 comprises metal films and / or metal oxide films 5 or the matrix 3 is formed from metal films and / or metal oxide films 5. The metal films and / or metal oxide films 5 are arranged in a lattice shape, the contacts 4 being provided at the two ends of each metal film and / or metal oxide film 5 or being connected to the conductive elements designed as metal films and / or metal oxide films 5.
    1b shows an example of an interconnection of two contacts 4 by means of an n-p transition at a node 51.
    The sensor structure 2 or the conductive elements are formed with different metals and / or metal oxides, e.g. B. from copper oxide and / or zinc oxide and / or tin oxide. The contacts 4 are connected to one another via the metal films and / or metal oxide films 5, the contacts 4 being able to be coupled and connected to one another as desired, as a result of which more than two gases can subsequently be measured.
    FIG. 2 shows a sensor arrangement 1 according to the invention. This comprises a sensor structure 2 with conductive elements arranged in a matrix 3 and a multiplicity of contacts 4, which is arranged on a substrate 9. The sensor structure 2 corresponds to the sensor structure 2 according to FIG. 1a. The conductive elements are in turn formed from metal films and / or metal oxide films 5 arranged in a grid. The metal films and / or metal oxide films 5 are also sensitized with nanoparticles 8.
    FIG. 3 shows a further sensor arrangement 1 according to the invention with a sensor structure 2, comprising conductive elements and contacts 4 formed from metals and / or metal oxides and arranged in a matrix 3. The matrix 3 comprises contact elements 7 made of different metal films and / or metal oxide films 5, / 29 which are connected to one another via metal oxide nanofibers 6. The nanofibers 6 are sensitized or functionalized with nanoparticles 8. The contact elements 7 are arranged directly on the substrate 9, whereas the nanofibers 6 are oxidized on the substrate 9 or a wafer.
    Another sensor arrangement 1 according to the invention is shown in FIG. 4. This sensor arrangement 1 essentially corresponds to the sensor arrangement 1 according to FIG. 3. Here, the contact elements 7 are applied to the substrate 9 and the nanofibers 6 between the contact elements 7 are printed on the substrate 9 in a connecting manner.
    In all design variants of a sensor arrangement 1 according to the invention, the conductive elements of the matrix 3 are at least partially formed from different metals and / or metal oxides, for example from copper oxide and / or zinc oxide and / or tin oxide. In addition, the conductive elements of the sensor structure 2 can be doped and / or p-doped.
    5, 6, 7 and 8 each show an image of contact elements 7 with nanofibers 6 taken with a scanning electron microscope. The nanofibers 6 are thermally oxidized during the manufacture of such a matrix 3 between the contact elements 7, whereas the contact elements 7 directly on a substrate 9 are applied, for example by vapor deposition, printing, sputtering or electrolytically. 5 to 7 show a matrix connection of the contact elements 7 via the nanofibers 6 or a matrix 3, whereas FIG. 8 shows a pure connection of contact elements 7 via nanofibers 6. These recordings are only exemplary, however, since the nanofibers 6 are each formed from only one metal oxide (copper oxide in FIGS. 5, 6 and 7; zinc oxide in FIG. 8). In a sensor arrangement 1 according to the invention, the matrix 3 is formed from different metal oxides in order to be able to determine and measure two or more gases in a gas mixture.
    FIG. 9 shows an image of a two-dimensional connection of contact elements 7 taken with a scanning electron microscope. A carrier of the sensor arrangement 1 can be, for example, a micro heating plate with which the sensor arrangement 1 can be brought to a defined temperature or subjected to defined temperature cycles.
    / 29
    In a method according to the invention for producing a sensor arrangement 1 for determining a plurality of gases, a substrate 9 is provided, onto which a sensor structure 2, comprising a matrix 3 of conductive elements and a large number of contacts 4, is applied. In a next step, the sensor structure 2 is sensitized to several gases, in particular with nanoparticles 8.
    The work leading to this invention was funded by the European Union, Seventh Framework Program (FP7 / 2007-2013) under grant agreement No. 611887.
    / 29
    权利要求:
    Claims (20)
    [1]
    Claims
    1. Sensor arrangement (1) for determining and optionally measuring a concentration of several gases, comprising a sensor structure (2) with conductive elements arranged in a matrix (3) and a plurality of contacts (4), the conductive elements with the contacts ( 4) are connected, characterized in that the conductive elements are formed with different metals and / or metal oxides in order to measure more than two gases isolated from one another in a gas mixture.
    [2]
    2. Sensor arrangement (1) according to claim 1, characterized in that the matrix (3) comprises metal films and / or metal oxide films (5).
    [3]
    3. Sensor arrangement (1) according to claim 1 or 2, characterized in that the sensor structure (2) comprises nanofibers (6).
    [4]
    4. Sensor arrangement (1) according to claim 3, characterized in that contact elements (7), in particular metallic and / or metal oxide contact elements (7), are provided, the nanofibers (6) being arranged between the contact elements (7).
    [5]
    5. Sensor arrangement (1) according to claim 3 or 4, characterized in that the nanofibers (6) are doped.
    [6]
    6. Sensor arrangement (1) according to one of claims 1 to 5, characterized in that the sensor structure (2) comprises nanoparticles (8) in order to sensitize sensors differently.
    [7]
    7. The sensor arrangement (1) according to one of claims 1 to 6, characterized in that the conductive elements arranged in the matrix (3) are at least partially formed from tin oxide and / or zinc oxide and at least partially from copper oxide, for example the tin oxide and / or zinc oxide is n-doped and the copper oxide is p-doped.
    13/29
    [8]
    8. Sensor arrangement (1) according to one of claims 1 to 7, characterized in that the matrix (3) comprises metal films and / or metal oxide films (5) and at a point of intersection between approximately mutually perpendicular metal films and / or metal oxide films (5) Transition between areas with different doping is formed.
    [9]
    9. Sensor arrangement (1) according to one of claims 1 to 8, characterized in that the sensor arrangement (1) is flexibly configurable.
    [10]
    10. Sensor arrangement (1) according to one of claims 1 to 9, characterized in that the sensor arrangement (1) comprises a heating device and / or a cooling device in order to bring the sensor arrangement (1) to a defined temperature or to subject defined temperature cycles.
    [11]
    11. Use of a sensor arrangement (1) according to one of claims 1 to 10 for the simultaneous determination of different gases.
    [12]
    12. A method for producing a sensor arrangement (1) for determining and optionally measuring a concentration of several gases, in particular a sensor arrangement (1) according to one of claims 1 to 11, comprising the following steps:
    - Providing a substrate (9),
    - Applying a sensor structure (2) made of different metals and / or metal oxides comprising conductive elements arranged in a matrix (3) and a plurality of contacts (4) on the substrate (9) and
    - Functionalization of sensors formed in the sensor structure (2).
    [13]
    13. The method according to claim 12, characterized in that the sensor structure (2) is functionalized with nanoparticles (8).
    [14]
    14. The method according to claim 12 or 13, characterized in that between the contact elements (7) arranged in the matrix (3), in particular metallic and / or metal oxide contact elements (7), nanofibers (6) are oxidized onto the substrate (9).
    14/29
    [15]
    15. The method according to any one of claims 12 to 14, characterized in that metal films and / or metal oxide films (5) are applied to the substrate (9).
    15/29
    1/5
    Fig. 1a
    Fig. 1b
    [16]
    16/29
    2/5
    Fig. 3
    Fig. 4
    [17]
    17/29
    3/5
    [18]
    18/29
    Fig. 6
    4/5
    Fig. 7
    Fig. 8
    [19]
    19/29
    5/5
    [20]
    20/29
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    同族专利:
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    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US4457161A|1980-10-09|1984-07-03|Hitachi, Ltd.|Gas detection device and method for detecting gas|
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    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    ATA51174/2016A|AT519492B1|2016-12-22|2016-12-22|Sensor arrangement for determining and optionally measuring a concentration of a plurality of gases and method for producing a sensor arrangement|ATA51174/2016A| AT519492B1|2016-12-22|2016-12-22|Sensor arrangement for determining and optionally measuring a concentration of a plurality of gases and method for producing a sensor arrangement|
    KR1020197017069A| KR20190099405A|2016-12-22|2017-12-12|Sensor device for determining and in some cases measuring the concentration of a plurality of gases, and a method of manufacturing the sensor device|
    JP2019528623A| JP2020503503A|2016-12-22|2017-12-12|Sensor mechanism for determining and possibly measuring the concentration of a plurality of gases, and a method of manufacturing the sensor structure|
    PCT/AT2017/060330| WO2018112486A1|2016-12-22|2017-12-12|Sensor arrangement for determining and possibly measuring a concentration of a plurality of gases, and method for producing a sensor arrangement|
    EP17816396.0A| EP3559659A1|2016-12-22|2017-12-12|Sensor arrangement for determining and possibly measuring a concentration of a plurality of gases, and method for producing a sensor arrangement|
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