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Khermit Edvanst Tekhnolodzhiz GmbKH

Overview
  • Total Patents
    25
  • GoodIP Patent Rank
    65,038
  • Filing trend
    ⇩ 68.0%
About

Khermit Edvanst Tekhnolodzhiz GmbKH has a total of 25 patent applications. It decreased the IP activity by 68.0%. Its first patent ever was published in 2017. It filed its patents most often in Russian Federation. Its main competitors in its focus markets materials and metallurgy, machine tools and measurement are MIYOSHI GOKIN KOGYO KK, CHEPETSKIJ MEKH ZD OAO CHMZ AOOT and TAIYUAN JINXI CHUNLEI COPPER IND CO LTD.

Patent filings in countries

World map showing Khermit Edvanst Tekhnolodzhiz GmbKHs patent filings in countries
# Country Total Patents
#1 Russian Federation 25

Patent filings per year

Chart showing Khermit Edvanst Tekhnolodzhiz GmbKHs patent filings per year from 1900 to 2020

Top inventors

# Name Total Patents
#1 Mityashkin Oleg Aleksandrovich 25
#2 Altynbaev Sergej Vladimirovich 25
#3 Uelst Dzhonaton Uolter Tomas 25
#4 Rasskazov Aleksej 25
#5 Ignatovskaya Anastasiya Albertovna 6
#6 Gorodnichev Rodion Mikhajlovich 5

Latest patents

Publication Filing date Title
RU2690869C1 METHOD OF MAKING WIRE FROM (α + β)-TITANIUM ALLOY FOR ADDITIVE TECHNOLOGY WITH INDUCTION HEATING AND WITH HIGH DEGREE OF DEFORMATION
RU2691815C1 METHOD OF MAKING WIRE FROM (α+β)-TITANIUM ALLOY FOR ADDITIVE TECHNOLOGY WITH CONTROL OF DEFORMATION TEMPERATURE TOLERANCE FIELD
RU2690262C1 METHOD OF MAKING WIRE FROM (α+β)-TITANIUM ALLOY FOR ADDITIVE TECHNOLOGY
RU2690263C1 METHOD OF MAKING WIRE FROM (α+β)-TITANIUM ALLOY FOR ADDITIVE TECHNOLOGY WITH HIGH SPEED AND DEGREE OF DEFORMATION
RU2690264C1 METHOD OF MAKING WIRE FROM (α+β)-TITANIUM ALLOY FOR ADDITIVE TECHNOLOGY WITH REMOVAL OF SURFACE LAYER
RU2690905C1 METHOD OF MAKING WIRE FROM (α+β)-TITANIUM ALLOY FOR ADDITIVE TECHNOLOGY WITH CONTROL OF TEMPERATURE TOLERANCE AND HIGH DEGREE OF DEFORMATION
RU2691690C2 Titanium alloy and the method of manufacturing the casing for products that experience cyclic loads
RU2656259C1 Method of selecting titanium alloy for ultrasonic waveguide
RU2661445C1 Method for estimating the energy intensity of a titanium alloy
RU2664665C1 Method of selecting titanium alloy for ultrasound waveguide
RU2664346C1 Method for producing titanium alloy billets for products experiencing variable mechanical loads
RU2691692C2 Titanium-based alloy
RU2706916C2 Blank for manufacturing elastic elements of a titanium-based alloy
RU2681089C2 Titanium-based alloy billet for elastic elements with energy-intensive structure
RU2681030C2 Titanium-based alloy
RU2681102C2 Method for producing a billet from a titanium-based alloy for elastic elements with energy-intensive structure
RU2661304C1 Method of estimating energy capacity of titanium alloy
RU2675673C2 Titanium-based alloy
RU2691787C2 Titanium-based alloy
RU2681033C2 Method for producing titanium alloy billets for products experiencing variable mechanical loads