Scientific and Practical Centre for Materials Research
https://www.physics.by/
220072 Minsk, P. Brovka str. 19
https://www.physics.by/
220072 Minsk, P. Brovka str. 19
Technology and equipment for production of metal-oxide composite materials for thick-film heating elements
COUNTRY OF ORIGIN
BelarusIDENTIFIER
TO3318PUBLISHED
2021-01-02LAST UPDATE
2021-04-06DEADLINE
Linked profile in other language
Responsible
Oleg Ignatenko
+375 17 227 7514
ignatenko@physics.by
+375 17 227 7514
ignatenko@physics.by
Summary
Centre for Materials Research offers a new method and equipment for the production of metal-oxide composite materials for thick-film heating elements. The technology reduces the production costs of the elements more than 10 times compared to existing methods. The Centre seeks cooperation with industrial partners for license agreement, commercial agreement with technical assistance or joint venture agreement, and R&D institutions for a research cooperation agreement.
Description
The Centre for Materials Research developed a new method and equipment for the production of metal-oxide composite materials for thick-film heating elements with new properties. Produced materials can be used as a replacement for silver, gold, palladium, platinum, and their alloys in film heating elements.
In the developed film element are used oxidized carbonyl iron powder that significantly reduces the cost of the element.
To eliminate the destruction of the element upon switching on and instantaneous heating, the existing heating elements are made sectional of small sections to minimize thermal expansion.
Fundamentally new technology is proposed in the developed element, which allows excluding the influence of the thermal expansion of the element and thus increases the reliability of the element.
As substrates for heating elements based on metal oxide composite materials, both metallic and non-metallic materials can be used. Heating elements can be applied to the substrate using both screen printing and 3D printing.
The institute seeks cooperation with industrial partners for license agreement, commercial agreement with technical assistance, or joint venture agreement. R&D organization interested in improving the technology and equipment for the production of metal-oxide composite materials for thick-film heating elements based on oxidized carbonyl iron powder under a research cooperation agreement.
In the developed film element are used oxidized carbonyl iron powder that significantly reduces the cost of the element.
To eliminate the destruction of the element upon switching on and instantaneous heating, the existing heating elements are made sectional of small sections to minimize thermal expansion.
Fundamentally new technology is proposed in the developed element, which allows excluding the influence of the thermal expansion of the element and thus increases the reliability of the element.
As substrates for heating elements based on metal oxide composite materials, both metallic and non-metallic materials can be used. Heating elements can be applied to the substrate using both screen printing and 3D printing.
The institute seeks cooperation with industrial partners for license agreement, commercial agreement with technical assistance, or joint venture agreement. R&D organization interested in improving the technology and equipment for the production of metal-oxide composite materials for thick-film heating elements based on oxidized carbonyl iron powder under a research cooperation agreement.
Advantages and Innovations
New technology and equipment for the production of metal-oxide composite materials based on oxidized carbonyl iron powder for thick-film heating elements reduce the production costs of the elements more than 10 times compared to existing methods using silver, gold, palladium, platinum, and their alloys in film heating elements.
To eliminate the destruction of the element upon switching on and instantaneous heating, the existing heating elements are made sectional of small sections to minimize thermal expansion. Fundamentally new technology is proposed in the developed element, which allows excluding the influence of the thermal expansion of the element and thus increases the reliability of the element.
To eliminate the destruction of the element upon switching on and instantaneous heating, the existing heating elements are made sectional of small sections to minimize thermal expansion. Fundamentally new technology is proposed in the developed element, which allows excluding the influence of the thermal expansion of the element and thus increases the reliability of the element.
Stage of development
Prototype available for demonstration (TRL7)
Funding source
State budged
Internal
Internal
IPR status
Patent(s) applied for but not yet granted
Secret know-how
Secret know-how
Sector group
Aeronautics, Space and Dual-Use Technologies
Intelligent Energy
Materials
Mobility
Nano and micro technologies
Intelligent Energy
Materials
Mobility
Nano and micro technologies
Client information
Type
R&D institution
Year established
1963
NACE keywords
C.28.99 - Manufacture of other special-purpose machinery n.e.c.
M.72.19 - Other research and experimental development on natural sciences and engineering
M.72.19 - Other research and experimental development on natural sciences and engineering
Turnover (in EUR)
1-10M
Already engaged in transnational cooperation
Yes
Additional comments
The Centre for Materials Research is engaged in solving fundamental and applied problems in the fields:
*Technology and equipment for the production of metal-oxide composite materials for thick-film heating elements
* Technology and equipment for the production of soft magnetic materials
* Creation of new magnetic, ferroelectric, semiconductor, metallic, superconducting, super hard, and optical materials
* Nanomaterials and nanostructures
* Non-destructive testing and technical diagnostics.
Applied research of the institute is related to a wide spectrum of scientific and engineering problems that are multidisciplinary in nature.
*Technology and equipment for the production of metal-oxide composite materials for thick-film heating elements
* Technology and equipment for the production of soft magnetic materials
* Creation of new magnetic, ferroelectric, semiconductor, metallic, superconducting, super hard, and optical materials
* Nanomaterials and nanostructures
* Non-destructive testing and technical diagnostics.
Applied research of the institute is related to a wide spectrum of scientific and engineering problems that are multidisciplinary in nature.
Languages spoken
English
Russian
Russian
Information about partnership
Type of partnership considered
Commercial agreement with technical assistance
Joint venture agreement
Research cooperation agreement
Joint venture agreement
Research cooperation agreement
Type and role of partner sought
The Centre wants to establish cooperation with an industrial partner or R&D organisation.
An industrial partner interested in the production of metal-oxide composite materials for thick-film heating elements based on oxidized carbonyl iron powder under a license agreement.
Industrial partner interested in using the equipment for the production of metal-oxide composite materials for thick-film heating elements based on oxidized carbonyl iron powder under a commercial agreement with technical assistance.
Joint venture agreement
Type of partner sought: industrial partner
Field of partner's activity: production of material or equipment for the production of metal-oxide composite materials for thick-film heating elements based on oxidized carbonyl iron powder.
Tasks to be performed: financing of joint venture activities, participation in enterprise management.
R&D organization interested in improving the technology and equipment for the production of metal-oxide composite materials for thick-film heating elements based on oxidized carbonyl iron powder under a research cooperation agreement.
Type and size of partner sought
> 500 MNE
> 500
251-500
SME 51-250
R&D Institution
> 500
251-500
SME 51-250
R&D Institution
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Statistics since 02.01.2021 14:03:43
Statistics since 02.01.2021 14:03:43