ADAPTIVE FLEXIBLE CIRCUIT SYSTEM FOR BATTERY-SUBSTRATE CONNECTIVITY

Abstract

Abstract The present disclosure provides a system for connecting a battery to a substrate within a housing. The system includes a flexible circuit positioned between said battery and said substrate. Said flexible circuit includes an elastic portion. A conductive trace integrated within said flexible circuit transmits electrical signals between said battery and said substrate. An adaptive positioning unit is coupled to said flexible circuit. Said adaptive positioning unit adjusts the position of said substrate relative to said battery, while the elastic portion maintains continuous electrical contact between the battery and the substrate, enabling stable connectivity. Dated 11 November 2024 Jigneshbhai Mungalpara IN/PA- 2640 Agent for the Applicant

Specification

Description:Mobile Vapor Filtration Device for Oil Separation
Abstract
A portable oil vapor filtration system includes a housing unit directing airflow through intake and exhaust ports. A rotatable filter disc positioned within said housing separates oil from vapor. A regeneration motor connects with said disc, enabling continuous oil extraction. Multiple mesh layers on the disc incorporate a central hub and a peripheral rim, efficiently directing separated oil externally. This arrangement promotes enhanced oil filtration and extraction within compact, mobile applications.


Dated 11 November 2024 Jigneshbhai Mungalpara
IN/PA- 2640
Agent for the Applicant


Mobile Vapor Filtration Device for Oil Separation
Abstract
A portable oil vapor filtration system includes a housing unit directing airflow through intake and exhaust ports. A rotatable filter disc positioned within said housing separates oil from vapor. A regeneration motor connects with said disc, enabling continuous oil extraction. Multiple mesh layers on the disc incorporate a central hub and a peripheral rim, efficiently directing separated oil externally. This arrangement promotes enhanced oil filtration and extraction within compact, mobile applications.


Dated 11 November 2024 Jigneshbhai Mungalpara
IN/PA- 2640
Agent for the Applicant













Claims
I/We Claim:
1. A system (100) for connecting a battery (102) to a substrate (104) within a housing (106), comprising:
a flexible circuit (108) positioned between said battery (102) and said substrate (104), said flexible circuit (108) comprising an elastic portion (110);
a conductive trace (112) integrated within said flexible circuit (108), said conductive trace (112) configured to transmit electrical signals between said battery (102) and said substrate (104); and
an adaptive positioning unit (114) coupled to said flexible circuit (108), said adaptive positioning unit (114) configured to adjust the position of said substrate (104) relative to said battery (102), wherein said elastic portion (110) maintains continuous electrical contact.
Claim 2:
The system (100) of claim 1, wherein said flexible circuit (108) is tensioned between said battery (102) and said substrate (104) along a first axis, such that the elasticity of said elastic portion (110) provides stable alignment of said conductive trace (112) with said battery (102), promoting seamless electrical conduction while mitigating mechanical stress exerted on said flexible circuit (108) due to movement within said housing (106).
Claim 3:
The system (100) of claim 1, wherein said adaptive positioning unit (114) is radially arranged around said battery (102) in a manner that maintains said substrate (104) in a spatial configuration relative to said battery (102), enabling said elastic portion (110) to exert a radial force that aligns said conductive trace (112) precisely for continuous electrical flow, thereby optimizing signal transmission.
Claim 4:
The system (100) of claim 1, wherein said substrate (104) is maintained in a transverse orientation relative to said flexible circuit (108), ensuring that said adaptive positioning unit (114) stabilizes said substrate (104) against rotational displacement within said housing (106), thereby preserving alignment of said conductive trace (112) to accommodate varying thermal expansions within said housing (106).
Claim 5:
The system (100) of claim 1, wherein said elastic portion (110) is configured with a biasing tension against said substrate (104), creating an axial force relative to said conductive trace (112) that dynamically adjusts to variations in spacing between said battery (102) and said substrate (104), thus ensuring uninterrupted electrical connectivity under operational shifts.
Claim 6:
The system (100) of claim 1, wherein said conductive trace (112) is arranged in parallel alignment with said elastic portion (110), allowing said adaptive positioning unit (114) to regulate the distance between said battery (102) and said substrate (104) effectively, thereby accommodating variations in mechanical positioning while preserving stable signal integrity.
Claim 7:
The system (100) of claim 1, further comprising a vibration-dampening layer affixed to said housing (106) and surrounding said flexible circuit (108), said vibration-dampening layer limiting mechanical oscillations within said housing (106) to reduce potential wear on said elastic portion (110), thereby enhancing the lifespan of said conductive trace (112) under repetitive operational stress.
Claim 8:
The system (100) of claim 1, wherein said elastic portion (110) is composed of a layered structure with differing tensile strengths, such that said elastic portion (110) provides graded flexibility to counteract thermal expansions of said battery (102) and said substrate (104), ensuring that the structural integrity of said flexible circuit (108) is preserved during fluctuating temperature conditions.
Claim 9:
The system (100) of claim 1, wherein said adaptive positioning unit (114) is configured to modify the alignment angle of said substrate (104) in response to detected deviations, such that said flexible circuit (108) remains in calibrated contact with said battery (102) and said substrate (104), thereby maintaining consistent signal transmission through said conductive trace (112).
Claim 10:
The system (100) of claim 1, further comprising an electromagnetic shielding layer positioned over said conductive trace (112), said shielding layer reducing electromagnetic interference within said housing (106), enhancing the clarity and accuracy of signal transmission from said battery (102) to said substrate (104), thereby supporting the functionality of said flexible circuit (108) under various operational environments.




Dated 11 November 2024 Jigneshbhai Mungalpara
IN/PA- 2640
Agent for the Applicant



Adaptive Flexible Circuit System for Battery-Substrate Connectivity
Abstract
The present disclosure provides a system for connecting a battery to a substrate within a housing. The system includes a flexible circuit positioned between said battery and said substrate. Said flexible circuit includes an elastic portion. A conductive trace integrated within said flexible circuit transmits electrical signals between said battery and said substrate. An adaptive positioning unit is coupled to said flexible circuit. Said adaptive positioning unit adjusts the position of said substrate relative to said battery, while the elastic portion maintains continuous electrical contact between the battery and the substrate, enabling stable connectivity.







Dated 11 November 2024 Jigneshbhai Mungalpara
IN/PA- 2640
Agent for the Applicant , Claims:Claims
I/We Claim:
1. A system (100) for connecting a battery (102) to a substrate (104) within a housing (106), comprising:
a flexible circuit (108) positioned between said battery (102) and said substrate (104), said flexible circuit (108) comprising an elastic portion (110);
a conductive trace (112) integrated within said flexible circuit (108), said conductive trace (112) configured to transmit electrical signals between said battery (102) and said substrate (104); and
an adaptive positioning unit (114) coupled to said flexible circuit (108), said adaptive positioning unit (114) configured to adjust the position of said substrate (104) relative to said battery (102), wherein said elastic portion (110) maintains continuous electrical contact.
Claim 2:
The system (100) of claim 1, wherein said flexible circuit (108) is tensioned between said battery (102) and said substrate (104) along a first axis, such that the elasticity of said elastic portion (110) provides stable alignment of said conductive trace (112) with said battery (102), promoting seamless electrical conduction while mitigating mechanical stress exerted on said flexible circuit (108) due to movement within said housing (106).
Claim 3:
The system (100) of claim 1, wherein said adaptive positioning unit (114) is radially arranged around said battery (102) in a manner that maintains said substrate (104) in a spatial configuration relative to said battery (102), enabling said elastic portion (110) to exert a radial force that aligns said conductive trace (112) precisely for continuous electrical flow, thereby optimizing signal transmission.
Claim 4:
The system (100) of claim 1, wherein said substrate (104) is maintained in a transverse orientation relative to said flexible circuit (108), ensuring that said adaptive positioning unit (114) stabilizes said substrate (104) against rotational displacement within said housing (106), thereby preserving alignment of said conductive trace (112) to accommodate varying thermal expansions within said housing (106).
Claim 5:
The system (100) of claim 1, wherein said elastic portion (110) is configured with a biasing tension against said substrate (104), creating an axial force relative to said conductive trace (112) that dynamically adjusts to variations in spacing between said battery (102) and said substrate (104), thus ensuring uninterrupted electrical connectivity under operational shifts.
Claim 6:
The system (100) of claim 1, wherein said conductive trace (112) is arranged in parallel alignment with said elastic portion (110), allowing said adaptive positioning unit (114) to regulate the distance between said battery (102) and said substrate (104) effectively, thereby accommodating variations in mechanical positioning while preserving stable signal integrity.
Claim 7:
The system (100) of claim 1, further comprising a vibration-dampening layer affixed to said housing (106) and surrounding said flexible circuit (108), said vibration-dampening layer limiting mechanical oscillations within said housing (106) to reduce potential wear on said elastic portion (110), thereby enhancing the lifespan of said conductive trace (112) under repetitive operational stress.
Claim 8:
The system (100) of claim 1, wherein said elastic portion (110) is composed of a layered structure with differing tensile strengths, such that said elastic portion (110) provides graded flexibility to counteract thermal expansions of said battery (102) and said substrate (104), ensuring that the structural integrity of said flexible circuit (108) is preserved during fluctuating temperature conditions.
Claim 9:
The system (100) of claim 1, wherein said adaptive positioning unit (114) is configured to modify the alignment angle of said substrate (104) in response to detected deviations, such that said flexible circuit (108) remains in calibrated contact with said battery (102) and said substrate (104), thereby maintaining consistent signal transmission through said conductive trace (112).
Claim 10:
The system (100) of claim 1, further comprising an electromagnetic shielding layer positioned over said conductive trace (112), said shielding layer reducing electromagnetic interference within said housing (106), enhancing the clarity and accuracy of signal transmission from said battery (102) to said substrate (104), thereby supporting the functionality of said flexible circuit (108) under various operational environments.




Dated 11 November 2024 Jigneshbhai Mungalpara
IN/PA- 2640
Agent for the Applicant

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