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1 / 319,660
1.112023003752PRÜFVERFAHREN FÜR KUNSTSTOFFFORMARTIKEL UND PRÜFVORRICHTUNG
DE 03.07.2025
Int.Class G01N 21/90
GPHYSICS
01MEASURING; TESTING
NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
21Investigating or analysing materials by the use of optical means, i.e. using sub-millimetre waves, infrared, visible or ultraviolet light
84Systems specially adapted for particular applications
88Investigating the presence of flaws, defects or contamination
90in a container or its contents
 Appl.No 112023003752 Applicant OMRON KIRIN TECHNO-SYSTEM CO., LTD. Inventor Tabuchi Hiroyasu

Ein Prüfbereich einer Flasche 2 als Kunststoffformartikel wird mit Anregungslicht wie UV-Licht oder dergleichen beleuchtet und es wird Prüfobjektlicht wie Fluoreszenz oder dergleichen von der Flasche 2 abgestrahlt, dessen Wellenlängenbereich ein anderer als der Wellenlängenbereich des Anregungslichts ist, der mit dem Anregungslicht beleuchtete Prüfbereich der Flasche 2 wird derart aufgenommen, dass der Wellenlängenbereich des Prüfobjektlichts im Wellenlängenbereich des Aufnahmeobjekts enthalten ist, während der Wellenlängenbereich des Anregungslichts aus dem Wellenlängenbereich des Aufnahmeobjekts ausgeschlossen ist, und auf Grundlage einer Intensität des Prüfobjektlichts in dem aufgenommenen Bild wird eine Beschaffenheit in Bezug auf wenigstens eine von der Form und der Struktur des Kunststoffformartikels in dem Prüfbereich wie beispielsweise das Vorhandensein von Formungsfehlern oder die Eignung eines Markierungsabschnitt geprüft. embedded image

2.102024138488Kompaktes spritzgegossenes optisches Modul zur Gaserfassung
DE 03.07.2025
Int.Class G01N 21/03
GPHYSICS
01MEASURING; TESTING
NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
21Investigating or analysing materials by the use of optical means, i.e. using sub-millimetre waves, infrared, visible or ultraviolet light
01Arrangements or apparatus for facilitating the optical investigation
03Cuvette constructions
 Appl.No 102024138488 Applicant Renesas Electronics America Inc. Inventor Fathi Mohammad Taghi

Optische Modulkomponente für einen Gassensor kann einen ersten Gehäuseabschnitt und einen zweiten Gehäuseabschnitt umfassen. Der erste Gehäuseabschnitt und der zweite Gehäuseabschnitt können konfiguriert sein, um miteinander verbunden zu werden und einen im Wesentlichen zylindrischen optischen Hohlraum zu bilden, wenn sie miteinander verbunden sind. Die optische Modulkomponente kann ferner umfassen: eine erste Öffnung zum Empfangen von Licht von einer Lichtquelle; mindestens eine zweite Öffnung zum Leiten von Licht von dem optischen Hohlraum zu einem Detektor; ein erstes gekrümmtes reflektierendes Element, das konfiguriert ist, um das Licht von der Lichtquelle in den optischen Hohlraum zu lenken; und ein zweites gekrümmtes reflektierendes Element, das konfiguriert ist, um das Licht von dem optischen Hohlraum zu dem Detektor zu lenken. Insbesondere können optische Achsen des ersten und des zweiten gekrümmten reflektierenden Elements in Bezug auf eine diametrale Ebene des optischen Hohlraums geneigt sein. embedded image

3.102024139300Gassensor
DE 03.07.2025
Int.Class G01N 27/406
GPHYSICS
01MEASURING; TESTING
NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
27Investigating or analysing materials by the use of electric, electrochemical, or magnetic means
26by investigating electrochemical variables; by using electrolysis or electrophoresis
403Cells and electrode assemblies
406Cells and probes with solid electrolytes
 Appl.No 102024139300 Applicant Niterra Co., Ltd. Inventor Nomura Masashi

Ein Gassensor umfasst: ein plattenförmiges Sensorelement (20), das sich in einer Axiallinien-(O)-richtung erstreckt und an einer Hauptfläche (20m1, 20m2) an deren Hinterendseite ein Elektroden-Pad (21a, 21b) aufweist; einen Metallanschluss (71), der sich in der Axiallinienrichtung erstreckt und elektrisch an das Elektroden-Pad angeschlossen ist; einen Separator (50) mit einem Aufnehmabschnitt (50h), der in der Axiallinienrichtung hindurchtritt und in welchem die Hinterendseite des Sensorelements und der Metallanschluss aufgenommen sind; und eine an einer Hinterendseite bezüglich des Separators angeordnete Öse (47), wobei der Aufnehmabschnitt eine Verjüngungsfläche (50s) aufweist, deren Durchmesser sich, indem sie sich der rückwärtsweisenden Fläche des Separators nähert, in einer Richtung senkrecht zur Hauptfläche erweitert, wobei die Öse an einer Vorderendseite eine Hervorstehung 47p aufweist, und ein Vorderende der Hervorstehung in eine Hinterendseite bezüglich eines Vorderendes der Verjüngungsfläche entlang der Axiallinienrichtung eingepasst ist, und der Metallanschluss die Hervorstehung kontaktiert. embedded image

4.102024139302Gassensor
DE 03.07.2025
Int.Class G01N 27/406
GPHYSICS
01MEASURING; TESTING
NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
27Investigating or analysing materials by the use of electric, electrochemical, or magnetic means
26by investigating electrochemical variables; by using electrolysis or electrophoresis
403Cells and electrode assemblies
406Cells and probes with solid electrolytes
 Appl.No 102024139302 Applicant Niterra Co., Ltd. Inventor Nomura Masashi

Ein Gassensor umfasst: ein plattenförmiges Sensorelement (20), das sich in einer Axiallinien-(O)-richtung erstreckt und an einer Hauptfläche (20m1, 20m2) an deren Hinterendseite ein Elektroden-Pad (21a, 21b) aufweist; einen Metallanschluss (71), der sich in der Axiallinienrichtung erstreckt und elektrisch an das Elektroden-Pad angeschlossen ist; und einen Separator (50) mit einem Aufnehmabschnitt (50h), der in der Axiallinienrichtung hindurchtritt und in welchem die Hinterendseite des Sensorelements und der Metallanschluss aufgenommen sind, womit der Metallanschluss gehaltert ist, wobei der Aufnehmabschnitt eine Verjüngungsfläche (50s) aufweist, deren Durchmesser sich, indem sie sich der rückwärtsweisenden Fläche des Separators nähert, in einer Richtung senkrecht zur Hauptfläche erweitert, und ein Hinterende (20e) des Sensorelements entlang der Axiallinienrichtung an einer Innenseite der Verjüngungsfläche angeordnet ist. embedded image

5.WO/2025/137774METHOD OF GENERATING AND SCREENING PEPTIDE APTAMER LIBRARIES FROM NATURALLY OCCURRING PROTEINS
WO 03.07.2025
Int.Class G16B 40/10
GPHYSICS
16INFORMATION AND COMMUNICATION TECHNOLOGY SPECIALLY ADAPTED FOR SPECIFIC APPLICATION FIELDS
BBIOINFORMATICS, i.e. INFORMATION AND COMMUNICATION TECHNOLOGY SPECIALLY ADAPTED FOR GENETIC OR PROTEIN-RELATED DATA PROCESSING IN COMPUTATIONAL MOLECULAR BIOLOGY
40ICT specially adapted for biostatistics; ICT specially adapted for bioinformatics-related machine learning or data mining, e.g. knowledge discovery or pattern finding
10Signal processing, e.g. from mass spectrometry or from PCR
 Appl.No PCT/CA2024/051737 Applicant MARSHALL, John G. Inventor MARSHALL, John G.
Provided herein are methods of making a peptide aptamer library from naturally occurring proteins and/or peptides. The peptide aptamer library can be generated from immunoglobulins, B cell receptors and/or T cell receptors of a host animal. Biological samples such as cells and biofluids can be used as a library of peptide aptamers. Also provided herein are methods to identify peptide aptamers that bind a target using the peptide aptamer library generated by the methods disclosed herein.
6.WO/2025/138299METHOD FOR IMPROVING H&E-STAINED IMAGE QUALITY OF SPATIO-TEMPORAL CHIP, REAGENT COMBINATION, KIT, AND DEVICE
WO 03.07.2025
Int.Class G01N 1/28
GPHYSICS
01MEASURING; TESTING
NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
1Sampling; Preparing specimens for investigation
28Preparing specimens for investigation
 Appl.No PCT/CN2023/143703 Applicant BGI SHENZHEN Inventor FAN, Guozhen
The present invention relates to the technical field of biology, and in particular to a method for improving the H&E-stained image quality of a spatio-temporal chip, a reagent combination, a kit, and a device. The present invention provides a new mounting medium, which uses a simple reagent and corresponding process design, achieving the same effects of mRNA in-situ capture and comprehensive enhancement of mRNA diffusion as a glycerol mounting medium, and effectively solving the problems of fading and color diffusion after tissue staining. Registration of an H&E image and a spatio-temporal expression matrix of a BGI Stereo-seq chip provides possibility for high-precision subcellular-level omics analysis.
7.WO/2025/140519CARGO INSPECTION DEVICE AND INSPECTION METHOD THEREOF
WO 03.07.2025
Int.Class G01V 5/00
GPHYSICS
01MEASURING; TESTING
VGEOPHYSICS; GRAVITATIONAL MEASUREMENTS; DETECTING MASSES OR OBJECTS; TAGS
5Prospecting or detecting by the use of ionising radiation, e.g. of natural or induced radioactivity
 Appl.No PCT/CN2024/143092 Applicant NUCTECH COMPANY LIMITED Inventor ZONG, Chunguang
A cargo inspection device and an inspection method thereof. The cargo inspection device comprises: a carrier (10) which is configured to move relative to an inspected cargo (G) in a preset direction during cargo inspection; a scanning imaging inspection apparatus (20) provided with a ray scanning assembly (21) used for scanning the inspected cargo (G) through rays; and a smell inspection apparatus (30) provided with a gas sampling assembly (31) for performing gas sampling on the inspected cargo (G), wherein the ray scanning assembly (21) and the gas sampling assembly (31) are both arranged on the carrier (10), and the ray scanning process realized by the ray scanning assembly (21) and the gas sampling process of the gas sampling assembly (31) at least partially coincide in time.
8.WO/2025/139709CT DEVICE
WO 03.07.2025
Int.Class G01N 23/046
GPHYSICS
01MEASURING; TESTING
NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
23Investigating or analysing materials by the use of wave or particle radiation, e.g. X-rays or neutrons, not covered by groups G01N3/-G01N17/178
02by transmitting the radiation through the material
04and forming images of the material
046using tomography, e.g. computed tomography
 Appl.No PCT/CN2024/137461 Applicant NUCTECH COMPANY LIMITED Inventor CHEN, Zhiqiang
Provided is a CT device, being related to the technical field of radiation scanning. The CT device comprises a rack; multiple supporting apparatuses arranged on the rack; a rotatable portion, the rotatable portion being able to rotate around a rotation axis when driven by a driving wheel, and the rotatable portion being jointly supported by the multiple supporting apparatuses during the rotation process; a scanning apparatus arranged on the rotatable portion, the scanning apparatus being used for scanning an object to be examined; an axial limiting mechanism comprising a first pressing roller set and a second pressing roller set, wherein the first pressing roller set and the second pressing roller set are separately arranged on the end faces on two sides of the rotatable portion in the direction of the rotation axis; the first pressing roller set and the second pressing roller set each comprise n pressing rollers, n being an integer larger than 3, and at least a part of the outer circumferential face of each pressing roller is in contact with the end face of the rotatable portion so as to limit the movement of the rotatable portion in the direction of the rotation axis.
9.WO/2025/139739METHOD FOR DISTINGUISHING QUALITY CONTROL SOLUTION FROM BIOLOGICAL SAMPLE
WO 03.07.2025
Int.Class G01N 27/416
GPHYSICS
01MEASURING; TESTING
NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
27Investigating or analysing materials by the use of electric, electrochemical, or magnetic means
26by investigating electrochemical variables; by using electrolysis or electrophoresis
416Systems
 Appl.No PCT/CN2024/137913 Applicant JIANGSU YUWELL POCTECH BIOTECHNOLOGY CO., LTD. Inventor WEI, Liang
A method for distinguishing a quality control solution from a biological sample, which method belongs to the technical field of electrochemical tests. The method for distinguishing a quality control solution from a biological sample comprises: making a working electrode come into contact with a sample to be tested, wherein the working electrode is a blank electrode or is covered with an inert substance that does not produce a chemical reaction with a biological sample; inputting an excitation signal sequence into the working electrode, wherein the excitation signal sequence comprises at least two consecutive or non-consecutive input signals, and each input signal is at a constant value; and respectively measuring an output signal sequence of a quality control solution and an output signal sequence of the biological sample in response to the excitation signal sequence, so as to distinguish the quality control solution from the biological sample. The method solves the problem whereby manually adjusting a quality control solution mode may lead to misoperation during a quality control process of existing electrode-type blood test apparatuses; in actual use, it is no longer necessary to perform mode setting on a quality control solution sample or a biological sample, thereby improving the usage convenience, and thus avoiding adverse results caused by misoperation; and there is no special requirement for the quality control solution, thereby facilitating the application and popularization.
10.WO/2025/138509IDENTIFICATION APPARATUS AND METHOD FOR CONTACT FATIGUE FAILURE CHARACTERISTIC VIBRATION SIGNAL
WO 03.07.2025
Int.Class G01N 3/06
GPHYSICS
01MEASURING; TESTING
NINVESTIGATING OR ANALYSING MATERIALS BY DETERMINING THEIR CHEMICAL OR PHYSICAL PROPERTIES
3Investigating strength properties of solid materials by application of mechanical stress
02Details
06Special adaptations of indicating or recording means
 Appl.No PCT/CN2024/090552 Applicant JIMEI UNIVERSITY Inventor CHEN, Junying
The present invention belongs to the technical field of contact fatigue testing. Disclosed are an identification apparatus and method for a contact fatigue failure characteristic vibration signal. The identification apparatus comprises a contact fatigue tester, wherein a microscopic observation module is fixed above an observation port of the contact fatigue tester, and the microscopic observation module comprises a stepper electric motor, a vertical guide rail, and a CCD camera provided with a microscope lens, which are sequentially connected. The method comprises: establishing a mapping relationship between spalling pit density characteristic information and a vibration signal by means of an LSTM algorithm; and on the basis of a vibration signal characteristic and the established mapping relationship, predetermining a contact fatigue failure. According to the identification apparatus and method for a contact fatigue failure characteristic vibration signal in the present invention, a specimen does not need to be repeatedly disassembled, in-situ measurement is achieved, errors caused by repeated installation are reduced, and the test efficiency is improved; and a mapping relationship between a spalling pit density and a vibration signal is established, and on the basis of the mapping relationship, a contact fatigue failure can be predetermined.
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