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slot bet com Manchester United New manager Ruben Amorim has warned the Red Devils fans that the team would suffer for long period. Amorim took charge of his first game as United Boss in their 1-1 draw at Ipswich Town at the weekend. Despite taking an early lead through Marcus Rashford, United were pegged back by the newly promoted club. “I know it is frustrating for the fans but we are changing so much in this moment with a lot of games,” Amorim said “We are going to suffer for a long period and we will try to win games. This will take time. “These guys had two days in trainings...”CNS, Ogalla, Remains Relentless In His War Against Oil ThievesCCAR_McKie 10 pass from Vasko (Hensley kick), 8:15. GAST_FG Rickman 28, 14:07. GAST_Brock 19 run (Rickman kick), 8:38. CCAR_Courtney 5 pass from Vasko (Hensley kick), 4:16. CCAR_FG Hensley 43, :01. CCAR_C.Washington 18 run (Hensley kick), 10:56. GAST_FG Rickman 30, 7:06. CCAR_McKie 31 pass from Vasko (Hensley kick), 2:44. GAST_Brock 1 run (pass failed), :25. CCAR_Vasko 10 run (Hensley kick), 9:50. CCAR_FG Hensley 23, 8:33. CCAR_Fletcher 39 interception return (Hensley kick), 7:13. GAST_Fleming 6 pass from Lowe (Hurst pass from Lowe), 4:36. RUSHING_Coastal Carolina, Washington 20-124, Vasko 13-68, Bennett 8-43, Price 5-26, Lloyd 3-10, Taylor 1-5, Duplessis 1-1, (Team) 2-(minus 2). Georgia St., Brock 14-71, Veilleux 11-62, Lowe 3-47, Dukes 2-11, Beasley 3-11. PASSING_Coastal Carolina, Vasko 13-17-1-200, (Team) 0-1-0-0, Duplessis 0-1-1-0, Kim 0-1-0-0. Georgia St., Veilleux 15-26-4-205, Lowe 2-6-0-21. RECEIVING_Coastal Carolina, McKie 5-81, Tucker 3-31, Karr 2-35, Duplessis 1-41, Berrong 1-7, Courtney 1-5. Georgia St., Hurst 8-131, Dukes 3-15, Riles 2-26, Fleming 2-18, Brock 1-21, Milton 1-15. MISSED FIELD GOALS_None.

In the world of hardware engineering, few embody the blend of precision, problem-solving, and innovation like Monish Katari. Monish has emerged as a distinguished professional in the field, developing high-performance hardware solutions and transforming complex challenges into streamlined designs that meet exacting standards. Monish's expertise in improving circuit board manufacturing within the semiconductor industry provides a strategic advantage for the U.S., enabling faster, more reliable production compared to foreign competitors, and strengthening America's leadership in critical technology sectors. Building a Foundation in System Architecture Monish's journey began with foundational roles in product development and system-level architecture, where he gained deep technical insights. His early experience in automotive technology and hardware development sectors equipped him with a meticulous approach to high-speed design, rigorous testing, and resilient development processes. Eager to refine every detail, Monish established himself early on as a professional who looked beyond routine tasks to drive product efficiency and reliability. These skills set the stage for Monish's rise to the forefront of hardware engineering. Leading with Innovation and Efficiency As Monish took on increasingly complex projects, his innovation skills became a defining feature of his career. Today, he is a principal figure at a prominent semiconductor company, leading projects that evaluate the boundaries of hardware design. One of his most notable accomplishments was reducing PCB re-spins by 85%, a breakthrough that accelerated development timelines and lowered costs. This achievement demonstrated not only Monish's technical expertise but also his ability to drive efficiency in complex projects. Monish's work with high-speed interfaces like PCIe, DDR4/DDR5, and LPDDR4/5 speaks to his depth of expertise in meeting the hardware industry's highest standards. Each project enhances his experience, constantly challenging him to innovate and to deliver solutions that maintain a balance of speed and reliability. His proficiency with these demanding technologies underscores his role as a leader capable of pushing the limits of hardware performance. Expertise in Advanced Hardware Design Monish's recent work in developing advanced controllers is a testament to his technical sophistication. Collaborating closely with signal integrity specialists, he has optimized high-speed memory interfaces that excel under rigorous conditions. His expertise extends across PCIe, Ethernet, FPGA, CPLD, SOCs, and ARM architectures, highlighting his adaptability in managing the diverse requirements of modern hardware design. In each project, Monish's ability to balance cost with performance is a standout strength. His meticulous approach to component selection and bill of materials (BOM) optimization ensures high-quality results without overshooting budgets. This attention to cost management has proven particularly valuable in projects where budget constraints are critical. His blend of technical and business acumen consistently enables him to deliver solutions that are both innovative and economically viable. Collaborative Leadership and Mentorship Monish's contributions extend beyond technical work; he is also a collaborative leader who recognizes the value of teamwork in hardware engineering. He has fostered a culture of communication and alignment with product objectives, working closely with validation, firmware, and operations teams to create a cohesive development environment. His influence reaches beyond engineering: as a mentor, Monish provides guidance to junior engineers, instilling a culture of continuous learning and fostering technical growth within his teams. His leadership style has been instrumental in reducing bottlenecks, allowing for smoother project progression, and enhancing team productivity. Monish's team at his current company benefits from his collaborative problem-solving approach, and together, they achieve results that consistently meet or exceed expectations. By setting a high bar for teamwork and precision, he has built a culture that values both accuracy and cooperative innovation. Embracing the Future of Technology In a rapidly evolving field, Monish's adaptability is one of his strongest assets. He embraces new tools, from advanced simulation techniques to innovative SI/PI analysis, ensuring his designs remain at the forefront of hardware engineering. This openness to innovation keeps him one step ahead, allowing him to integrate advancements into each project and consistently exceed industry standards. Monish's commitment to improvement reflects his forward-thinking approach and ensures his contributions remain impactful as technology progresses. A Legacy of Excellence Monish Katari's career is marked by a dedication to innovation, precision, and efficiency. His journey, from foundational roles in product development to his current leadership position, highlights his technical mastery and collaborative spirit. From reducing PCB re-spins to pioneering high-speed hardware interfaces, Monish's work exemplifies the qualities that define excellence in hardware engineering. Each challenge he tackles reinforces his legacy as a professional who not only excels individually but also elevates those around him. In every project, Monish continues to redefine what it means to be a hardware engineer, setting ambitious standards for peers and inspiring the next generation of innovators. His contributions, marked by adaptability and a relentless pursuit of quality, have left an indelible mark on the industry and will continue to shape the future of hardware engineering for years to come.CDT Report: Borrowed Boats: The PRC’s “Embedded Propaganda” in Local African Media

Do users know how to judge the accuracy of a vertical machining center? 11-21-2024 09:44 PM CET | Industry, Real Estate & Construction Press release from: ABNewswire Methods for Judging the Accuracy of Vertical Machining Centers In the field of mechanical processing, the accuracy of vertical machining centers is of crucial importance to the processing quality. As an operator, accurately judging its accuracy is a key step in ensuring the processing effect. The following will elaborate on the methods for judging the accuracy of vertical machining centers. Determination of Related Elements of the Test Piece Materials, Tools and Cutting Parameters of the Test PieceThe selection of test piece materials, tools and cutting parameters has a direct impact on the judgment of accuracy. These elements are usually determined according to the agreement between the manufacturing factory and the user and need to be properly recorded.In terms of cutting speed, it is approximately 50 m/min for cast iron parts; while for aluminum parts, it is approximately 300 m/min. The appropriate feed rate is roughly within (0.05 - 0.10) mm/tooth. In terms of cutting depth, the radial cutting depth for all milling operations should be 0.2 mm. The reasonable selection of these parameters is the basis for accurately judging the accuracy subsequently. For example, too high a cutting speed may lead to increased tool wear and affect the processing accuracy; improper feed rate may cause the surface roughness of the processed part to fail to meet the requirements. Fixing of the Test PieceThe fixing method of the test piece is directly related to the stability during the processing. The test piece needs to be conveniently installed on a special fixture to ensure the maximum stability of the tool and the fixture. The installation surfaces of the fixture and the test piece must be flat, which is a prerequisite for ensuring the processing accuracy. At the same time, the parallelism between the installation surface of the test piece and the clamping surface of the fixture should be inspected.In terms of the clamping method, a suitable way should be used to enable the tool to penetrate and process the full length of the center hole. For example, it is recommended to use countersunk screws to fix the test piece, which can effectively avoid interference between the tool and the screws. Of course, other equivalent methods can also be selected. The total height of the test piece depends on the selected fixing method. A suitable height can ensure the stability of the position of the test piece during the processing process and reduce the accuracy deviation caused by factors such as vibration. Dimensions of the Test PieceAfter multiple cutting operations, the external dimensions of the test piece will decrease and the hole diameter will increase. When used for acceptance inspection, in order to accurately reflect the cutting accuracy of the machining center, it is recommended to select the final contour machining test piece dimensions to be consistent with those specified in the standard. The test piece can be repeatedly used in cutting tests, but its specifications should be kept within plus-minus 10% of the characteristic dimensions given by the standard. When the test piece is used again, a thin-layer cutting should be carried out to clean all the surfaces before conducting a new precision cutting test. This can eliminate the influence of the residue from the previous processing and make each test result more accurately reflect the current accuracy status of the machining center. Positioning of the Test PieceThe test piece should be placed in the middle position of the X stroke of the vertical machining center and at an appropriate position along the Y and Z axes suitable for the positioning of the test piece and the fixture as well as the length of the tool. However, when there are special requirements for the positioning position of the test piece, they should be clearly specified in the agreement between the manufacturing factory and the user. Correct positioning can ensure the accurate relative position between the tool and the test piece during the processing process, thereby effectively ensuring the processing accuracy. If the test piece is inaccurately positioned, it may lead to problems such as processing dimension deviation and shape error. For example, deviation from the central position in the X direction may cause dimension errors in the length direction of the processed workpiece; improper positioning along the Y and Z axes may affect the accuracy of the workpiece in the height and width directions. Specific Detection Items and Methods of Processing Accuracy Detection of Dimensional AccuracyAccuracy of Linear DimensionsUse measuring tools (such as calipers, micrometers, etc.) to measure the linear dimensions of the processed test piece. For example, measure the length, width, height and other dimensions of the workpiece and compare them with the designed dimensions. For machining centers with high accuracy requirements, the dimension deviation should be controlled within a very small range, generally at the micron level. By measuring the linear dimensions in multiple directions, the positioning accuracy of the machining center in the X, Y, Z axes can be comprehensively evaluated. Accuracy of Hole DiameterFor the holes processed, tools such as internal diameter gauges and coordinate measuring machines can be used to detect the hole diameter. The accuracy of the hole diameter includes not only the requirement that the diameter size meets the requirements, but also indicators such as cylindricity. If the hole diameter deviation is too large, it may be caused by factors such as tool wear and spindle radial runout. Detection of Shape AccuracyDetection of FlatnessUse instruments such as levels and optical flats to detect the flatness of the processed plane. Place the level on the processed plane and determine the flatness error by observing the change in the position of the bubble. For high-precision processing, the flatness error should be extremely small, otherwise it will affect subsequent assembly and other processes. For example, when processing the guide rails of machine tools and other planes, the flatness requirement is extremely high. If it exceeds the allowable error, it will cause the moving parts on the guide rails to run unsteadily. Detection of RoundnessFor the circular contours (such as cylinders, cones, etc.) processed, a roundness tester can be used to detect. The roundness error reflects the accuracy situation of the machining center during the rotation movement. Factors such as the rotation accuracy of the spindle and the radial runout of the tool will affect the roundness. If the roundness error is too large, it may lead to imbalance during the rotation of mechanical parts and affect the normal operation of the equipment. Detection of Position AccuracyDetection of ParallelismDetect the parallelism between processed surfaces or between holes and surfaces. For example, to measure the parallelism between two planes, a dial indicator can be used. Fix the dial indicator on the spindle, make the indicator head contact the measured plane, move the workbench, and observe the change in the dial indicator reading. Excessive parallelism error may be caused by factors such as the straightness error of the guide rail and the inclination of the workbench. Detection of PerpendicularityDetect the perpendicularity between processed surfaces or between holes and surface by using tools such as try squares and perpendicularity measuring instruments. For example, when processing box-type parts, the perpendicularity between the various surfaces of the box has an important impact on the assembly and use performance of the parts. The perpendicularity error may be caused by the perpendicularity deviation between the coordinate axes of the machine tool. Evaluation of Dynamic Accuracy Detection of VibrationDuring the processing process, use vibration sensors to detect the vibration situation of the machining center. Vibration may lead to problems such as increased surface roughness of the processed part and accelerated tool wear. By analyzing the frequency and amplitude of the vibration, it is possible to determine whether there are abnormal vibration sources, such as unbalanced rotating parts and loose components. For high-precision machining centers, the vibration amplitude should be controlled at a very low level to ensure the stability of the processing accuracy. Detection of Thermal DeformationThe machining center will generate heat during long-term operation, thereby causing thermal deformation. Use temperature sensors to measure the key components (such as the spindle and the guide rail) temperature changes and combine with measuring instruments to detect the change in the processing accuracy. Thermal deformation may lead to gradual changes in the processing dimensions. For example, the elongation of the spindle under high temperature may cause dimension deviations in the axial direction of the processed workpiece. To reduce the impact of thermal deformation on the accuracy, some advanced machining centers are equipped with cooling systems to control the temperature. Consideration of Repositioning Accuracy Comparison of the Accuracy of Multiple Processing of the Same Test PieceBy repeatedly processing the same test piece and using the above detection methods to measure the accuracy of each processed test piece. Observe the repeatability of indicators such as dimensional accuracy, shape accuracy and position accuracy. If the repositioning accuracy is poor, it may lead to unstable quality of batch-processed workpieces. For example, in mold processing, if the repositioning accuracy is low, it may cause the cavity dimensions of the mold to be inconsistent, affecting the use performance of the mold. In conclusion, as an operator, to comprehensively and accurately judge the accuracy of vertical machining centers, it is necessary to start from multiple aspects such as the preparation of test pieces (including materials, tools, cutting parameters, fixing and dimensions), the positioning of test pieces, the detection of various items of processing accuracy (dimensional accuracy, shape accuracy, position accuracy), the evaluation of dynamic accuracy, and the consideration of repositioning accuracy. Only in this way can the machining center meet the processing accuracy requirements during the production process and produce high-quality mechanical parts. Media Contact Company Name: Qingdao Taizheng Precision Machinery Co., Ltd. Email:Send Email [ https://www.abnewswire.com/email_contact_us.php?pr=do-you-know-how-to-judge-the-accuracy-of-a-vertical-machining-center ] Phone: 13605328581 Address:C-101, Building 31, Zhongnan High tech Jimo Technology Innovation Industrial Park, No. 76 Dazhong 1st Road, Jimo District, Qingdao Country: China Website: https://www.ncmillingmachine.com/ This release was published on openPR.Hicks 6-9 1-1 16, Konan Niederhauser 4-6 4-7 12, Baldwin 2-8 8-8 12, Dilione 3-6 0-2 6, P.Johnson 5-8 3-4 15, Kern 9-12 2-5 20, Nzeh 1-2 1-1 3, Dunn 0-4 0-0 0, Carter 0-2 0-2 0, Stewart 0-0 1-2 1. Totals 30-57 20-32 85. Dean 5-10 1-2 13, Tsimbila 0-0 0-0 0, J.Johnson 5-11 5-6 15, Medor 3-6 1-2 8, Richardson 0-2 0-0 0, Rivera 7-12 1-5 15, Tripp 5-9 2-2 13, Smith 0-1 0-2 0, Riley 0-1 0-1 0, Pettis 0-1 0-0 0, Zona 1-1 0-0 2. Totals 26-54 10-20 66. Halftime_Penn St. 42-34. 3-Point Goals_Penn St. 5-14 (Hicks 3-5, P.Johnson 2-3, Carter 0-1, Dilione 0-1, Dunn 0-1, Kern 0-1, Baldwin 0-2), Fordham 4-18 (Dean 2-5, Tripp 1-1, Medor 1-2, Pettis 0-1, Smith 0-1, Richardson 0-2, Rivera 0-2, J.Johnson 0-4). Fouled Out_Tsimbila. Rebounds_Penn St. 37 (Kern 13), Fordham 27 (Dean 9). Assists_Penn St. 13 (Baldwin 7), Fordham 16 (Medor, Richardson, Tripp 3). Total Fouls_Penn St. 19, Fordham 24.

NEW YORK CITY, NY / ACCESSWIRE / November 26, 2024 / The RENN Fund, Inc. (NYSE American:RCG) (the "Fund") announced today a record date for the Fund's year-end distribution. The record date will be December 16, 2024 and Pay-Date of December 27, 2024. The Fund will make an announcement on or about December 23, 2024 with the distribution rate per share. As the per share rate will not be available prior to the record date, the Fund will trade with due bills beginning December 16, 2024, and up through and including the last business day prior to the New York Stock Exchange established Ex-Date. The New York Stock Exchange will set the Ex-Date once the per share rate has been announced. Disclosures: Fund shares are subject to investment risk, including possible loss of principal invested. No fund is a complete investment program and you may lose money investing in the Fund. An investment in the Fund may not be appropriate for all investors. Additional information about the Fund, including performance and portfolio characteristics, is available at https://horizonkinetics.com/investment-strategies/renn-fund-inc-nyse-rcg/ . About Horizon Kinetics LLC Horizon Kinetics Holding Corporation (OTC: HKHC), through its subsidiary investment manager, Horizon Kinetics Asset Management LLC ("Horizon"), is an investment advisory firm and the Investment Advisor to the Fund. Horizon provides independent proprietary research and investment advisory services for long-only and alternative value-based investing strategies, including the full suite of Kinetics Mutual Funds, Inc. The firm has offices in New York City, White Plains, New York and Summit, New Jersey. For more information, please visit Horizon's websites below: http://www.horizonkinetics.com http://www.kineticsfunds.com . Contact: Jay Kesslen Email: jkesslen@horizonkinetics.com Phone: (646) 495-7333 SOURCE: RENN FUND INC View the original on accesswire.com

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Police had to use pepper spray to break up the players, who threw punches and shoves in the melee that overshadowed the rivalry game. Ohio State police said in a statement “multiple officers representing Ohio and Michigan deployed pepper spray.” Ohio State police will investigate the fight, according to the statement. After the Ohio State players confronted their bitter rivals at midfield, defensive end Jack Sawyer grabbed the top of the Wolverines' flag and ripped it off the pole as the brawl moved toward the Michigan bench. Eventually, police officers rushed into the ugly scene. Ohio State coach Ryan Day said he understood the actions of his players. “There are some prideful guys on our team who weren't going to sit back and let that happen,” Day said. The two Ohio State players made available after the game brushed off questions about it. Michigan running back Kalel Mullings, who rushed for 116 yards and a touchdown, didn't like how the Buckeyes players involved themselves in the Wolverines' postgame celebration. He called it “classless.” “For such a great game, you hate to see stuff like that after the game," he said in an on-field interview with Fox Sports. “It’s just bad for the sport, bad for college football. But at the end of the day, you know some people got to — they got to learn how to lose, man. ... We had 60 minutes, we had four quarters, to do all that fighting.” Michigan coach Sherrone Moore said everybody needs to do better. “So much emotions on both sides," he said. "Rivalry games get heated, especially this one. It’s the biggest one in the country, so we got to handle that better.” Get poll alerts and updates on the AP Top 25 throughout the season. Sign up here . AP college football: https://apnews.com/hub/ap-top-25-college-football-poll and https://apnews.com/hub/college-footballAUTODESK, INC. ANNOUNCES FISCAL 2025 THIRD QUARTER RESULTS