› Measurement unit: kg/m3. Full name: kilogram/cubic metre. Plural form: kilograms/cubic meter. Symbol: kg/m 3. Category type: density. Scale factor: 1 ›› SI unit: kilogram/cubic meter. The SI derived unit for density is the kilogram/cubic meter. 1 kilogram/cubic meter is equal to 1 kg/m3. ››

Convert gram/cubic centimetre to kilogram/cubic metre More information from the unit converter How many g/cm3 in 1 kg/m3? The answer is We assume you are converting between gram/cubic centimetre and kilogram/cubic metre. You can view more details on each measurement unit g/cm3 or kg/m3 The SI derived unit for density is the kilogram/cubic meter. 1 g/cm3 is equal to 1000 kilogram/cubic meter. Note that rounding errors may occur, so always check the results. Use this page to learn how to convert between grams/cubic centimeter and kilograms/cubic meter. Type in your own numbers in the form to convert the units! Quick conversion chart of g/cm3 to kg/m3 1 g/cm3 to kg/m3 = 1000 kg/m3 2 g/cm3 to kg/m3 = 2000 kg/m3 3 g/cm3 to kg/m3 = 3000 kg/m3 4 g/cm3 to kg/m3 = 4000 kg/m3 5 g/cm3 to kg/m3 = 5000 kg/m3 6 g/cm3 to kg/m3 = 6000 kg/m3 7 g/cm3 to kg/m3 = 7000 kg/m3 8 g/cm3 to kg/m3 = 8000 kg/m3 9 g/cm3 to kg/m3 = 9000 kg/m3 10 g/cm3 to kg/m3 = 10000 kg/m3 Want other units? You can do the reverse unit conversion from kg/m3 to g/cm3, or enter any two units below Common density conversions Metric conversions and more provides an online conversion calculator for all types of measurement units. You can find metric conversion tables for SI units, as well as English units, currency, and other data. Type in unit symbols, abbreviations, or full names for units of length, area, mass, pressure, and other types. Examples include mm, inch, 100 kg, US fluid ounce, 6'3", 10 stone 4, cubic cm, metres squared, grams, moles, feet per second, and many more!

Random converter 1 liter/kilogram [L/kg] = 0,001 meter³/kilogram [m³/kg]Lebih lanjut tentang Volume KhususThe working fluid steam rotates the turbine of this gas-powered power station as it expands through it. Gambaran umumApplicationsTwo-Phase SystemsHeating, Ventilating, and Air Conditioning TechnologySolar Thermal CollectorsHeat Pipe SystemsHow Two-Phase Systems WorkPressure, Temperature, and Specific Volume Specific Volume in Pressure CookersGambaran umumRefrigeration cycle. Step 1. The hot refrigerant, which was compressed by the compressor is cooled by outside air flow and condensed in this heat exchanger of a window air conditionerSpecific volume indicates volume per unit of mass — a property of substances and materials that is often used in thermodynamics. It is the inverse of density. To find a specific volume, we divide the volume by mass. For gases, it can also be found by using pressure, temperature, and molecular mass. While volume per unit of mass is more common, sometimes specific volume may refer to volume per molecular weight. We can usually tell from the context which specific volume is used. The units for the specific volume by mass and specific volume by moles are different, so it is also possible to tell which specific volume is meant by looking at the units. Specific volume per mass is measured in m³/kg, L/kg, or ft³/lb and units derived from those, while molar volume is measured in m³/mol, and units derived from it. In some cases the latter is called molar volume or molar specific we compare solids, liquids, and gases we will note that it is much easier to change density and specific volume for gases. Incidentally, while density is more commonly used when talking about liquids and solids, specific volume is more often used when working with gases. If we talk about systems that have both gas and a liquid within them, it is common to use specific volume when talking about both states of a cycle. Step 2. The cooled refrigerant in the liquid form is routed through the expansion valve and enters the evaporator heat exchanger shown in this picture. The warm room air is blown across the cold evaporator and is cooled thereTwo-Phase SystemsSystems that have within them a substance in two different states of matter liquid and gas, or liquid and solid are known as two-phase systems. A mix of ice and water in a cup is one example. A system that has both liquid and vapor of this liquid in it, for example in a boiler of a gas-powered power station, or in a nuclear reactor, or in an air conditioner is another. We may want to observe how such a system behaves when temperature or pressure changes, in particular — whether the amount of substance in one phase increases or decreases as these parameters change. This is where we would use specific volume. To quantify properties of a two-phase system in general it is also convenient to use specific let us consider some examples of two-phase systems and how they are used in our daily lives and technology. After that, we will discuss the relevance of specific Ventilating, and Air Conditioning TechnologyRefrigeration cycle. Step 3. The gaseous refrigerant from the evaporator enters the compressor, is compressed there to a higher pressure, and then enters the condenser heat exchanger and the refrigeration cycle is repeatedIn many cases heating, ventilating, and air conditioning HVAC installations consist of a two-phase system. When the heating is on, it is sometimes the case that water is heated to produce steam, and the hot steam is then circulated through the pipes of the system to heat the room. Hot water is often used in many systems to carry the heat along the pipes. Some of these HVAC systems use boilers, which are heating devices. The water inside them is heated by burning some fuel, often fossil fuel. Coal is commonly used, and so is natural the air conditioning is in operation the air in the room is cooled by a substance called refrigerant that alternates between a gas and a liquid state. Initially, this substance is cooled as a gas in the heat exchanger called a condenser. When it cools, it condenses, meaning that it becomes a liquid. It is then sent by a compressor through the system to cool the room, and in this process, it evaporates in another heat exchanger called an evaporator and becomes a gas again, as it warms up. It is then returned to the first heat exchanger condenser to repeat the outside unit of a mini-split air conditioner systemChanging from liquid to gas requires much energy. During the cooling process the system absorbs energy from the room to heat the refrigerant, and in the process cools the room. The condenser in the air conditioner cools the gas by releasing the energy and industrial refrigerators work using the same principle. Some of the HVAC systems work as a single unit, and some are a combination of a separate heater and an air thermal collectors are used for heatingSolar Thermal CollectorsThermal collectors within solar panels, in particular the flat plate collectors, work in a somewhat similar fashion as well. Solar energy enters the system through the front panel and heats air or liquid such as water or antifreeze. This thermal heat is used for heating or to provide hot pipes are highly efficient thermal conductors due to very high heat transfer during boiling and condensation of a liquid inside a heat pipeHeat Pipe SystemsIn a heat pipe system, the process is similar to the air conditioner, except that it is not air that is cooled but surfaces made from various solid materials such as metals. The heat of these surfaces vaporizes the liquid in the heat pipe. The rest of the process is similar, with the gas condensing when cooled, and then returning back into the system. Some examples of cooling agents are helium, alcohol, and mercury. These systems are often used in electronic components especially in computers, to cool parts that are subject to rapid or extreme heating. They are also used in space in very extreme Two-Phase Systems WorkIn a two-phase system, there is usually a set of conditions in which both states can coexist within the system. If the properties of a substance are outside of the range of these conditions, then the substance can only be in one state, as we discuss in more detail we work with a two-phase system, it is the change in pressure, not in specific volume, that causes the temperature changes. However, this pressure change also changes the specific volume. In some situations, we have a special case where the pressure and the temperature are constant, but the specific volume is changing. This happens if we have a system with constant pressure, at a temperature that allows two phases of the same substance to co-exist. In this case, once the system reaches this temperature, if it stays constant, the liquid within the system starts turning into gas, and the specific volume increases as a result. Of course in this case the total volume of the system changes as well, so this is only possible if the system is flexible enough to accommodate that. In systems that have a set volume and mass and do not allow the specific volume to change, as we see in the example of a pressure cooker, the process is different. In our system, the increase in specific volume will continue until the liquid evaporates and the system reaches equilibrium design of boilers and steam turbines used in power plants like the gas-powered plant shown in this picture requires a detailed understanding of two-phase flow heat transfer and pressure drop just looked at what happens if we keep the pressure constant. Now let us consider the case when the temperature is constant and we increase the pressure. For each substance, there is a specific range of pressure for which the substance can only exist in a gas state. There is also a range of pressure for which the gas and the liquid state of the substance can exist together in the same system. As we change pressure, the specific volume of the substance also also has a specific value above which the substance cannot coexist as a liquid and a gas in one system. This value for temperature is called the critical temperature, and the value for pressure is called critical pressure. In thermodynamics, the critical temperature and the critical pressure combined are called the critical Temperature, and Specific Volume In thermodynamics pressure, temperature, and specific volume are three values that form a special relationship. It is convenient to use them for describing a thermodynamic system because they are easy to measure. As we have discussed earlier, as long as we work with a single-phase substance, a change in pressure or a change in temperature causes a decrease or an increase in specific volume. It depends on the substance, but for most gases increase in pressure means a decrease in specific volume, as long as we keep the temperature constant. On the other hand, an increase in temperature results in an increase in specific volume if the pressure is constant. This relationship means that if we control the specific volume, we can also control either pressure or temperature. This is the principle used in the pressure a pressure cooker, the boiling point of water increases up to 121 °C 250 °F at the sea level at a pressure of 1 bar or ~15 psi above the existing atmospheric pressureSpecific Volume in Pressure CookersA pressure cooker is generally filled with food that is in a liquid state. Often there is also some food in a solid state, but a liquid is necessary for this type of cooking to work. When the lid is closed, the vapor cannot escape from the pressure cooker chamber except through the steam vent with the pressure regulator on it. Therefore during the cooking process, the total volume is the same. The goal for pressure cooking is to cook the food inside at a higher temperature without allowing too much liquid to evaporate. This shortens the cooking time. We do need to generate some steam, however, because the additional goal that we try to achieve with a pressure cooker is to use hot steam for cooking. Steam has a much higher heat capacity than air, meaning that it is more efficient at storing energy. This is why it is used in pressure cooking. The energy efficiency of steam and the fact that we cook food at temperatures of about 120°С means that we can cook our food faster and use less energy to achieve the same result as we would with boiling or cooking in the keep the mass and the volume of the contents of the pressure cooker more or less constant by preventing most of the steam from escaping. This ensures that the specific volume also stays somewhat constant. As we discussed earlier, if one among either the pressure, the temperature, or the specific volume is kept constant, then the magnitude of the other two variables depends on each other. Thus, if we increase temperature, as we do during pressure cooking, then the pressure inside increases also. Eventually, we would reach the temperature-pressure balance, such that further increase in external temperature would result in evaporation. This is the maximum temperature that can be reached for the given specific volume and pressure. This is when we lower the heat to keep the temperature and the pressure constant for the remaining cooking a pressure cooker is not only energy-efficient. It also reduces cooking times, as we mentioned before, and thus heats the kitchen a lot less, which is useful during the warm seasons. It can also be argued that pressure cooking is a healthy option because it does not require additional oil as does frying or kesulitan menerjemahkan satuan pengukuran ke bahasa lainnya? Bantuan tersedia! Posting pertanyaan Anda di TCTerms dan Anda akan mendapatkan jawaban dari penerjemah teknis berpengalaman dalam hitungan menit. MekanikMekanika merupakan cabang fisika, yang mempelajari perilaku badan fisik saat terkena gaya atau pemindahan, dan efek lanjutan badan tersebut pada KhususVolume khusus dari zat adalah rasio volume zat terhadap massanya. Volume ini adalah kebalikan dari kerapatan dan merupakan sifat benda secara untuk volume khusus adalah meter kubik per kilogram [m³/kg].Menggunakan Pengonversi Volume KhususPengonversi satuan online ini memungkinkan konversi yang cepat dan akurat antar banyak satuan pengukuran, dari satu sistem ke sistem lainnya. Laman Konversi Satuan menyediakan solusi bagi para insinyur, penerjemah, dan untuk siapa pun yang kegiatannya mengharuskan bekerja dengan kuantitas yang diukur dalam satuan bisa menggunakan pengonversi online ini untuk mengonversi antar beberapa ratus satuan termasuk metrik, Inggris dan Amerika dalam 76 kategori, atau beberapa ribu pasang termasuk akselerasi, luas, listrik, energi, gaya, panjang, cahaya, massa, aliran massa, kepadatan, kapasitas massa, daya, tekanan, tegangan, suhu, waktu, torsi, kecepatan, kekentalan, volume dan kapasitas, aliran volume, dan masih banyak lagi. Catatan Bilangan bulat angka tanpa desimal atau eksponen dianggap akurat hingga 15 digit dan jumlah digit maksimum setelah titik desimal adalah kalkulator ini, lambang E digunakan untuk mewakili angka yang terlalu kecil atau terlalu besar. Lambang E adalah format alternatif dari lambang ilmiah a • 10x. Misalnya = 1,103 • 106 = 1,103E+6. Di sini E dari eksponen mewakili “• 10^”, yaitu “kali sepuluh yang dinaikkan ke kekuatan ”. Lambang E umumnya digunakan dalam kalkulator dan oleh ilmuwan, matematikawan dan satuan untuk dikonversikan dalam kotak sebelah kiri yang berisi daftar satuan untuk dikonversi dalam kotak sebelah kanan yang berisi daftar nilai misalnya “15” ke dalam kotak Dari di sebelah akan muncul di kotak Hasil dan di kotak Anda bisa masukkan nilai ke kotak Ke di sebelah kanan dan membaca hasil konversi di kotak Dari dan work hard to ensure that the results presented by converters and calculators are correct. However, we do not guarantee that our converters and calculators are free of errors. All of the content is provided “as is”, without warranty of any kind. Syarat dan Anda dapati kesalahan dalam teks atau perhitungan, atau Anda membutuhkan pengonversi lainnya, yang tidak Anda temukan di sini, silakan beritahukan kami!Saluran YouTube untuk Pengonversi Unit

1m3beton k300 butuh koral 1021 kg. 154 m3 beton K300 butuh pasir = 154 x 1021= 157.234 kg. 1m3 pasir itu beratnya 1400kg, jadi perlu pasir 157.234kg / 1800kg = 87,35 m3 dibulatkan jadi 88m3. perlu koral 88m3. Jadi untuk membuat jalan beton ukuran 140m x 5,5m x 0,2m itu diperlukan pasir 75m3, semen 1272 zak, koral 88m3. Begitulah gambaran

Measurement unit kg/m3 Full name kilogram/cubic metre Plural form kilograms/cubic meter Symbol kg/m3 Category type density Scale factor 1 SI unit kilogram/cubic meter The SI derived unit for density is the kilogram/cubic meter. 1 kilogram/cubic meter is equal to 1 kg/m3. Convert kg/m3 to another unit Convert kg/m3 to Valid units must be of the density type. You can use this form to select from known units Convert kg/m3 to Sample conversions kg/m3 kg/m3 to tonne/cubic centimetre kg/m3 to ton/cubic yard [long] kg/m3 to nanogram/litre kg/m3 to megagram/cubic centimetre kg/m3 to pound/gallon [ kg/m3 to grain/gallon [ kg/m3 to megagram/millilitre kg/m3 to tonne/cubic decimetre kg/m3 to ton/cubic yard [short] kg/m3 to tonne/millilitre Convert Metric Dates Salary Chemistry Forum Search Privacy Bibliography Contact © 2023

Satuanmetrik berat yang sama dengan seperseribu kilogram. Konversi Gram ke Kilogram kg = g 1000.0 Kilogram Kilogram adalah satuan dasar dari massa dalam Sistem Satuan Internasional (SI), dan diterima dalam basis hari-hari sebagai satuan

Convert kilogram/cubic metre to kilogram/litre More information from the unit converter How many kg/m3 in 1 kilogram/liter? The answer is 1000. We assume you are converting between kilogram/cubic metre and kilogram/litre. You can view more details on each measurement unit kg/m3 or kilogram/liter The SI derived unit for density is the kilogram/cubic meter. 1 kilogram/cubic meter is equal to kilogram/liter. Note that rounding errors may occur, so always check the results. Use this page to learn how to convert between kilograms/cubic meter and kilograms/liter. Type in your own numbers in the form to convert the units! 1 kg/m3 to kilogram/liter = kilogram/liter 10 kg/m3 to kilogram/liter = kilogram/liter 50 kg/m3 to kilogram/liter = kilogram/liter 100 kg/m3 to kilogram/liter = kilogram/liter 200 kg/m3 to kilogram/liter = kilogram/liter 500 kg/m3 to kilogram/liter = kilogram/liter 1000 kg/m3 to kilogram/liter = 1 kilogram/liter Want other units? You can do the reverse unit conversion from kilogram/liter to kg/m3, or enter any two units below Common density conversions Metric conversions and more provides an online conversion calculator for all types of measurement units. You can find metric conversion tables for SI units, as well as English units, currency, and other data. Type in unit symbols, abbreviations, or full names for units of length, area, mass, pressure, and other types. Examples include mm, inch, 100 kg, US fluid ounce, 6'3", 10 stone 4, cubic cm, metres squared, grams, moles, feet per second, and many more!

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kalkulator konversi m3 ke kg