Call Of Chernobyl Crash On Start [EXCLUSIVE]

It's so strange. Everyone talks about how much the vanilla Stalker games crash. But none of them have EVER crashed for me. The only one that crashes is a mod, which claims to fix crashes...rather ironic. Even when I played the other games for hundreds of hours, I never started crashing. But with CoC, the crashes were infrequent at first, common later on, and now they happen at least 30 times an hour (no exaggeration) when quicksaving, when exiting the main menu, when tabbing back in, loading a new area, loading a new section of the current area, etc. I feel like the game has gone to a 25% chance of crashing at any time to a 80% chance over the past 45 hours of gameplay.

It's crashing on ui_main_menu.script because _g.script is failing to load at startup. _g.script is where the SendScriptCallback() function is defined. Since you say you also get the crash with 1.2 by itself, I'm going to guess your 1.2 install files might be corrupt or incomplete. You might try redownloading them (I use the torrent version myself, for convenience). If you want to verify the MD5 hashes of your files against mine here they are:

Call Of Chernobyl Crash On Start

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In December 1986, after six months of investigation, the team discovered with the help of a remote camera that an intensely radioactive mass more than 2 metres (6 ft 7 in) wide had formed in the basement of Unit Four. The mass was called "the elephant's foot" for its wrinkled appearance.[89] It was composed of melted sand, concrete, and a large amount of nuclear fuel that had escaped from the reactor. The concrete beneath the reactor was steaming hot, and was breached by now-solidified lava and spectacular unknown crystalline forms termed chernobylite. It was concluded that there was no further risk of explosion.[51]

Fires started in what remained of the unit 4 building, giving rise to clouds of steam and dust, and fires also broke out on the adjacent turbine hall roof (bitumen, a flammable material, had been used in its construction). A first group of 14 firemen arrived on the scene of the accident at 01:28. Over 100 fire-fighters from the site and called in from Pripyat were needed, and it was this group that received the highest radiation exposures. Reinforcements were brought in until about 04:00, when 250 firemen were available and 69 firemen participated in fire control activities. The INSAG-1 report4 states: "The fires on the roofs of units 3 and 4 were localized at 02:10 and 02:20 respectively, and the fire was quenched at 05:00." Unit 3, which had continued to operate, was shut down at this time, and units 1 and 2 were shut down in the morning of 27 April.

Fires started in what remained of the Unit 4 building, giving rise to clouds of steam and dust, and fires also broke out on the adjacent turbine hall roof and in various stores of diesel fuel and inflammable materials. Over 100 fire-fighters from the site and called in from Pripyat were needed, and it was this group that received the highest radiation exposures and suffered the greatest losses in personnel. A first group of 14 firemen arrived on the scene of the accident at 1.28 a.m. Reinforcements were brought in until about 4 a.m., when 250 firemen were available and 69 firemen participated in fire control activities. By 2.10 a.m., the largest fires on the roof of the machine hall had been put out, while by 2.30 a.m., the largest fires on the roof of the reactor hall were under control. These fires were put out by 05:00 hr of the same day, but by then the graphite fire had started. Many firemen added to their considerable doses by staying on call on site. The intense graphite fire was responsible for the dispersion of radionuclides and fission fragments high into the atmosphere. The emissions continued for about twenty days, but were much lower after the tenth day when the graphite fire was finally extinguished.

Nuclear plant operators start by documenting each power plant site. This analysis of 'extreme scenarios' followed what ENSREG called a progressive approach "in which protective measures are sequentially assumed to be defeated" from starting conditions which "represent the most unfavourable operational states." The operators have to explain their means to maintain "the three fundamental safety functions (control of reactivity, fuel cooling confinement of radioactivity)" and support functions for these, "taking into account the probable damage done by the initiating event."

As for commercial customers, two billionaires are waiting for Starship besides Musk. One is Jared Isaacman, who funded and flew on a SpaceX Crew Dragon mission called Inspiration4 last September and started the Polaris Program, a cadre of commercial astronauts and charity fundraisers who are expected to crew the first Starship flights with humans on board. As for lunar ambitions, Japanese entrepreneur Yusaku Maezawa and Denis Tito, an American entrepreneur who self-funded a trip to the ISS on a Russian spacecraft in 2001, have both paid SpaceX unspecified amounts for around-the-moon trips.

Nuclear energy is the energy in the nucleus, or core, of an atom. Atoms are tiny units that make up all matter in the universe, and energy is what holds the nucleus together. There is a huge amount of energy in an atom's dense nucleus. In fact, the power that holds the nucleus together is officially called the "strong force."

Nuclear energy can be used to create electricity, but it must first be released from the atom. In the process of nuclear fission, atoms are split to release that energy.

A nuclear reactor, or power plant, is a series of machines that can control nuclear fission to produce electricity. The fuel that nuclear reactors use to produce nuclear fission is pellets of the element uranium. In a nuclear reactor, atoms of uranium are forced to break apart. As they split, the atoms release tiny particles called fission products. Fission products cause other uranium atoms to split, starting a chain reaction. The energy released from this chain reaction creates heat.

The heat created by nuclear fission warms the reactor's cooling agent. A cooling agent is usually water, but some nuclear reactors use liquid metal or molten salt. The cooling agent, heated by nuclear fission, produces steam. The steam turns turbines, or wheels turned by a flowing current. The turbines drive generators, or engines that create electricity.

Rods of material called nuclear poison can adjust how much electricity is produced. Nuclear poisons are materials, such as a type of the element xenon, that absorb some of the fission products created by nuclear fission. The more rods of nuclear poison that are present during the chain reaction, the slower and more controlled the reaction will be. Removing the rods will allow a stronger chain reaction and create more electricity.

As of 2011, about 15 percent of the world's electricity is generated by nuclear power plants. The United States has more than 100 reactors, although it creates most of its electricity from fossil fuels and hydroelectric energy. Nations such as Lithuania, France, and Slovakia create almost all of their electricity from nuclear power plants.

Nuclear Food: Uranium

Uranium is the fuel most widely used to produce nuclear energy. That's because uranium atoms split apart relatively easily. Uranium is also a very common element, found in rocks all over the world. However, the specific type of uranium used to produce nuclear energy, called U-235, is rare. U-235 makes up less than one percent of the uranium in the world.

The Soviet government ordered the operators of Chernobyl to perform a test on their reactor. The test was supposed to measure how long the spinning generator would continue producing electricity after the reactor was shut down before it slowed and stopped. The test was to happen with the reactor at low power. As the operators were about to start slowly and carefully bringing the reactor to low power, the utility company called and said that a nearby coal plant just shut down unexpectedly and asked Chernobyl to stay at full power for a while longer to keep the nearby homes lit. After peak hours, the operators brought the plant to low power rapidly. Nuclear engineers can explain to you that this kind of shut-down would result in an unusually large amount of Xenon build-up in the reactor fuel. Xenon eats up neutrons, thus making the chain reaction more difficult to maintain. Because of this, the operators were surprised when the reactor went to a lower power than they had expected. be457b7860