update can not be installed if there isnt at least 100gb of free space! the install files are 2,26GB and I have still 20GB free. what a bullshit is that? why do the people who released this version, dont write anything about this problem?!

C O D E X P R E S E N T S Gears 5 Update 1 (c) Xbox Game Studios Release Date : 10/2019 Protection : Steam+Arxan+EAC+XboxLive Discs : 1 Genre : Action For list of changes read included patchnotes.txt - Extract - Run setup.exe and install update - Copy crack from CODEX dir to installdir - Play

Gears 5 Update 1-CODEX

The 5th entry in the Gears of War franchise is coming in 2019. The gameplay trailer hints that the story will closely follow only two characters as opposed to the entire crew, like in previous games. Gears 5 is sure to be intense! More information, including system requirement details, will be updated when it is made available. Update: July 5, 2019Big news today for Gears of War fans! The official system requirements were announced earlier today for Gears 5!We just finished updating the test page so head on over and check it out!

We added two new codes on February 4, 2023, for Devil Fruit resets and title spins. Be quick, these codes expire soon. We also moved a bunch of codes to the expired section that no longer work, as well as updated our info on how to propery redeem codes in the game.

The easiest way to keep track of when new codes are dropped for A One Piece Game is to bookmark this page! We check for new codes regularly, so you don't need to. To hunt for codes on your own, we recommended joining the Boss Studios official Discord server, as this is where you can get the latest info on codes, updates, and sneak peeks.

A One Piece Game codes are given out by the developers at Boss Studios to celebrate like milestones and new updates. They expire pretty quickly, so make sure to grab them quickly. The vast majority of codes for the game can be redeemed for Race Rerolls which is essentially a free roll on the in-game gacha "race" system. These races determine your abilities, cosmetics, and gameplay.

Here at VULKK.com we have a ton of useful New World Guides and more and more are being published regularly. We also have all of the news and updates covered to keep you up-to-date with all things New World!

Codex Madrid I has a great correspondence with the Codex Atlanticus: A series of devices, such as gears, springs, hinges, mechanical elements of clocks, scales, weights, screws, etc., are outlined in the Codex Atlanticus and developed in the Codex Madrid I, with drawings with great detail and quality. There is a connection with other codices: the Codices Forster or Manuscripts A and H, from Codices Paris (Cerveró-Meliá et al., 2020).

What mechanical elements can be seen in the Codex Madrid I? Ball and rolling bearings; several types of gears and gear sets; cams and followers; flywheels; belt drives (open and crossed); chain drives (several models of chain); ratchet and pawl mechanism, joints; couplings; and many more drawings of mechanical elements and functional studies that, in this work, we will try to summarize all of them in 100 drawings.

In the Mechanisms Drawings Box 1 (MDB-1) several drawings of gears are shown. Among others, various devices can be seen: a study of gears with teeth or pins (MDB-1.1); spur gears (MDB-1.4); bevel gears (with teeth, MDB-1.2, or with pins MDB-1.7); worm gear systems (MDB-1.3, MDB-1.8 and MDB-1.10); crown wheel gears (MDB-1.5 and MDB-1.11); internal gear (MDB-1.12); rack and gears (MDB-1.9); or a study of transmission ratio in gears (MDB-1.6).

In the Mechanisms Drawings Box 2 (MDB-2) several drawings of screw spindles are shown (MDB-2.4, MDB-2.5, MDB-2.6 and MDB-2.8). Drawings of a double helix reversing mechanism (MDB-2.9), a gear regulator de-vice (MDB-2.1), a rack and gears drive (MDB-2.10), a planetary-epicyclic gear (MDB-2.7) or train gear reduction systems (MDB-2.2 and MDB-2.3) can also be seen in MDB-2.

This artefact was among wreckage retrieved from a shipwreck off the coast of the Greek island Antikythera in 1901.[10][11] On 17 May 1902, it was identified as containing a gear by archaeologist Valerios Stais.[12] The device, housed in the remains of a wooden-framed case of (uncertain) overall size 34 cm 18 cm 9 cm (13.4 in 7.1 in 3.5 in),[13][14] was found as one lump, later separated into three main fragments which are now divided into 82 separate fragments after conservation efforts. Four of these fragments contain gears, while inscriptions are found on many others.[13][14] The largest gear is approximately 13 centimetres (5.1 in) in diameter and originally had 223 teeth.[15]

In 2008, a team led by Mike Edmunds and Tony Freeth at Cardiff University used modern computer x-ray tomography and high resolution surface scanning to image inside fragments of the crust-encased mechanism and read the faintest inscriptions that once covered the outer casing of the machine. This suggests that it had 37 meshing bronze gears enabling it to follow the movements of the Moon and the Sun through the zodiac, to predict eclipses and to model the irregular orbit of the Moon, where the Moon's velocity is higher in its perigee than in its apogee. This motion was studied in the 2nd century BC by astronomer Hipparchus of Rhodes, and it is speculated that he may have been consulted in the machine's construction.[16] There is speculation that a portion of the mechanism is missing and it also calculated the positions of the five classical planets.

The mechanism was operated by turning a small hand crank (now lost) which was linked via a crown gear to the largest gear, the four-spoked gear visible on the front of fragment A, gear b1. This moved the date pointer on the front dial, which would be set to the correct Egyptian calendar day. The year is not selectable, so it is necessary to know the year currently set, or by looking up the cycles indicated by the various calendar cycle indicators on the back in the Babylonian ephemeris tables for the day of the year currently set, since most of the calendar cycles are not synchronous with the year. The crank moves the date pointer about 78 days per full rotation, so hitting a particular day on the dial would be easily possible if the mechanism were in good working condition. The action of turning the hand crank would also cause all interlocked gears within the mechanism to rotate, resulting in the simultaneous calculation of the position of the Sun and Moon, the moon phase, eclipse, and calendar cycles, and perhaps the locations of planets.[49]

The mechanism is remarkable for the level of miniaturisation and the complexity of its parts, which is comparable to that of fourteenth-century astronomical clocks. It has at least 30 gears, although mechanism expert Michael Wright has suggested that the Greeks of this period were capable of implementing a system with many more gears.[49]

Evans et al. suggest that to display the mean positions of the five classical planets would require only 17 further gears that could be positioned in front of the large driving gear and indicated using individual circular dials on the face.[66]

A table of the gears, their teeth, and the expected and computed rotations of various important gears follows. The gear functions come from Freeth et al. (2008)[7] and those for the lower half of the table from Freeth and Jones 2012.[5] The computed values start with 1 year/revolution for the b1 gear, and the remainder are computed directly from gear teeth ratios. The gears marked with an asterisk (*) are missing, or have predecessors missing, from the known mechanism; these gears have been calculated with reasonable gear teeth counts.[7][15]

There are several gear ratios for each planet that result in close matches to the correct values for synodic periods of the planets and the Sun. The ones chosen above seem to provide good accuracy with reasonable tooth counts, but the specific gears that may have been used are, and probably will remain, unknown.[5]

It is very probable that there were planetary dials, as the complicated motions and periodicities of all planets are mentioned in the manual of the mechanism. The exact position and mechanisms for the gears of the planets is not known. There is no coaxial system but only for the Moon. Fragment D that is an epicycloidal system is considered as a planetary gear for Jupiter (Moussas, 2011, 2012, 2014) or a gear for the motion of the Sun (University of Thessaloniki group).The Sun gear is operated from the hand-operated crank (connected to gear a1, driving the large four-spoked mean Sun gear, b1) and in turn drives the rest of the gear sets. The Sun gear is b1/b2 and b2 has 64 teeth. It directly drives the date/mean sun pointer (there may have been a second, "true sun" pointer that displayed the Sun's elliptical anomaly; it is discussed below in the Freeth reconstruction). In this discussion, reference is to modelled rotational period of various pointers and indicators; they all assume the input rotation of the b1 gear of 360 degrees, corresponding with one tropical year, and are computed solely on the basis of the gear ratios of the gears named.[4][7][68]

The Moon train starts with gear b1 and proceeds through c1, c2, d1, d2, e2, e5, k1, k2, e6, e1, and b3 to the Moon pointer on the front face. The gears k1 and k2 form an epicyclic gear system; they are an identical pair of gears that don't mesh, but rather, they operate face-to-face, with a short pin on k1 inserted into a slot in k2. The two gears have different centres of rotation, so the pin must move back and forth in the slot. That increases and decreases the radius at which k2 is driven, also necessarily varying its angular velocity (presuming the velocity of k1 is even) faster in some parts of the rotation than others. Over an entire revolution the average velocities are the same, but the fast-slow variation models the effects of the elliptical orbit of the Moon, in consequence of Kepler's second and third laws. The modelled rotational period of the Moon pointer (averaged over a year) is 27.321 days, compared to the modern length of a lunar sidereal month of 27.321661 days. As mentioned, the pin/slot driving of the k1/k2 gears varies the displacement over a year's time, and the mounting of those two gears on the e3 gear supplies a precessional advancement to the ellipticity modelling with a period of 8.8826 years, compared with the current value of precession period of the moon of 8.85 years.[4][7][68] 2ff7e9595c