What is a pascal equal to? Calculator for converting pressure in bar to MPa, kgf and psi

Pressure- this is a quantity that is equal to the force acting strictly perpendicular to a unit surface area. Calculated using the formula: P = F/S. The international number system assumes the measurement of such a value in pascals (1 Pa is equal to a force of 1 newton per area of ​​1 square meter, N/m2). But since this is a fairly low pressure, measurements are often indicated in kPa or MPa. In various industries it is customary to use their own number systems, in the automotive, pressure can be measured: in bars, atmospheres, kilograms of force per cm² (technical atmosphere), mega pascals or psi(psi).

For quick translation units of measurement should be guided by the following relationship of values ​​to each other:

1 MPa = 10 bar;

100 kPa = 1 bar;

1 bar ≈ 1 atm;

3 atm = 44 psi;

1 PSI ≈ 0.07 kgf/cm²;

1 kgf/cm² = 1 at.

Why do you need a pressure unit conversion calculator?

The online calculator will allow you to quickly and accurately convert values ​​from one pressure measurement unit to another. This conversion can be useful to car owners when measuring compression in the engine, checking the pressure in the fuel line, inflating tires to the required value (very often it is necessary convert PSI to atmospheres or MPa to bar when checking pressure), filling the air conditioner with freon. Since the scale on the pressure gauge may be in one number system, and in the instructions in a completely different one, there is often a need to convert bars into kilograms, megapascals, kilograms of force per square centimeter, technical or physical atmospheres. Or, if you need a result in the English numeral system, then pound-force per square inch (lbf in²), in order to exactly correspond to the required instructions.

How to use an online calculator

In order to use the instant conversion of one pressure value to another and find out how much bar will be in MPa, kgf/cm², atm or psi you need:

1. In the left list, select the unit of measurement with which you want to convert;
2. In the right list, set the unit to which the conversion will be performed;
3. Immediately after entering a number in any of the two fields, the “result” appears. So you can convert from one value to another and vice versa.

For example, the number 25 was entered into the first field, then depending on the selected unit, you will calculate how many bars, atmospheres, megapascals, kilograms of force produced per cm² or pound-force per square inch. When this same value was put in another (right) field, the calculator will calculate the inverse ratio of the selected physical quantities pressure.

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1 pascal [Pa] = 1.01971621297793E-05 kilogram-force per square meter. centimeter [kgf/cm²]

Initial value

Converted value

pascal exapascal petapascal terapascal gigapascal megapascal kilopascal hectopascal decapascal decipascal centipascal millipascal micropascal nanopascal picopascal femtopascal attopascal newton per square meter meter newton per square meter centimeter newton per square meter millimeter kilonewton per square meter meter bar millibar microbar dyne per sq. centimeter kilogram-force per square meter. meter kilogram-force per square meter centimeter kilogram-force per square meter. millimeter gram-force per square meter centimeter ton-force (kor.) per sq. ft ton-force (kor.) per sq. inch ton-force (long) per sq. ft ton-force (long) per sq. inch kilopound-force per sq. inch kilopound-force per sq. inch lbf per sq. ft lbf per sq. inch psi poundal per sq. foot torr centimeter of mercury (0°C) millimeter of mercury (0°C) inch of mercury (32°F) inch of mercury (60°F) centimeter of water. column (4°C) mm water. column (4°C) inch water. column (4°C) foot of water (4°C) inch of water (60°F) foot of water (60°F) technical atmosphere physical atmosphere decibar walls per square meter barium pieze (barium) Planck pressure seawater meter foot sea ​​water (at 15°C) meter of water. column (4°C)

Featured Article

The Science of Coffee Making: Pressure

High pressure is often used during cooking, and in this article we will talk about what pressure is used when brewing coffee. We will look at the espresso technique, in which coffee is prepared using hot water under pressure. First, we'll talk about coffee preparation in general, what substances are extracted from coffee beans during the brewing process, and the different methods of preparing coffee. After that, we'll discuss in detail the role of pressure in making espresso, and also see how other variables affect the taste of coffee.

Coffee

People have been enjoying coffee since at least the fifteenth century, and perhaps even earlier, although we do not have precise records of earlier coffee preparations. Historians claim that the people of Ethiopia were the first to drink coffee, and that from there this drink spread to Yemen and other neighboring countries, and from these countries it already came to Europe. According to some reports, Sufi Muslims used coffee in religious rituals. For many years, coffee was banned in the Arab world by conservative members of the Islamic clergy due to its unusual properties, but the ban was eventually relaxed. The Church in Europe also disapproved of coffee for some time due to its popularity in the Muslim world, but soon came to terms with the growing popularity of the drink in Europe. Since then, coffee has been popular all over the world. Coffee is probably the first thing that comes to mind when you think about a typical morning. So what is coffee, how to prepare it, and why do we love it so much?

Coffee beans are the seeds of the berries of a plant in the madder family ( Rubiaceae). There are many different plant species in this family, but the most widely used for making coffee is the Arabian Coffee Arabica(Arabica variety) and Congolese Coffea canephora coffee tree (robusta variety), with the Arabica variety being more popular. IN English language coffee berries are sometimes called cherries for their color and shape, but they have no relation to the cherry tree. The coffee beans are first cooked, i.e. roasted, and then prepared into coffee, and during these processes, various substances, including aromatic oils and solid particles, are extracted. These substances create the special taste and aroma of coffee and give it invigorating properties.

As far as we know, one of the first ways to prepare coffee was to boil coffee beans in water. While trying different brewing methods, people noticed that if coffee is in contact with hot water for too long, the drink becomes bitter, and if, on the contrary, the coffee is not brewed long enough, then it becomes sour. Therefore, they were developed various ways preparations that ensure the best extraction. Trying different methods During preparation, bartenders in coffee shops noticed that pressure improved the preparation process and the taste of the finished drink, and thus the espresso technique was born.

Coffee has been prepared for centuries different ways, and everything we know about making coffee comes from hundreds of years of experimentation in the kitchen. It was thanks to these experiments that coffee lovers determined optimal temperature, roasting and brewing times, grind size, and the use of pressure during the brewing process.

Substances that are obtained by extraction from coffee beans during the preparation process

The taste of coffee and its special properties depend on the chemicals that are obtained during the extraction process of roasting coffee beans and preparing the coffee itself. In this section we will talk about the main substances and how different preparation methods affect their extraction.

Caffeine

Caffeine is one of the main substances obtained during extraction from coffee beans. It is thanks to him that coffee gives those who drink it a boost of energy. Caffeine also gives the drink its characteristic bitterness. When coffee is prepared using the espresso technique, more caffeine is obtained from the ground coffee compared to other preparation methods. But this does not mean that if you drank one shot of espresso, you received a greater dose of caffeine than if you drank a cup of coffee, for example, prepared in a drip coffee maker. After all, espresso shots are much smaller in volume than portions in large cups in which coffee prepared in a drip coffee maker is served. Therefore, although espresso coffee has a much higher concentration of caffeine, the total amount of caffeine in a shot of espresso is less than in coffee prepared by other methods, since espresso is drunk in very small portions.

Trigonelline

Trigonelline is one of the substances that gives coffee its special rich caramel aroma. The flavor is not obtained directly from trigonelline during preparation, but during roasting of the coffee beans. Due to heat treatment, trigonelline breaks down into aromatic substances called pyridines.

Acids

Coffee contains acids. You've probably noticed this if you've ever poured cream into your espresso coffee and it curdled. The three main acids in coffee are citric, quinic, and malic. There are other acids in coffee, but in very small quantities.

Quinic acid makes coffee sour if it is kept at temperatures above 80°C for a long time, for example if it is left in a warming pot.

Malic acid gives coffee notes of apple and pear and improves its taste. It also adds sweetness to the coffee.

Some other acids that are extracted into the finished drink are phosphoric acid, which gives coffee its fruity notes, acetic acid, which gives it lime notes, and tartaric acid, which gives coffee its grape flavor.

Carbohydrates

Coffee contains a number of carbohydrates that make coffee sweet. You probably haven't even noticed before that coffee is actually a little sweet, especially if you think of coffee as a bitter drink. But there is sweetness in it, and you can notice it with practice, especially if you drink espresso good quality, brewed by a person who knows how to make coffee properly. The brown color of roasted coffee is also due to carbohydrates. When cooked, coffee beans change color from green to brown, as the Maillard reaction occurs in carbohydrates under the influence of temperature. The color of golden brown bread, fried meat, vegetables, and other foods is also the result of this reaction.

The balanced extraction of all these and several other components produces the diverse and unique variations of coffee taste and aroma that we love so much. Below we will look at a number of methods for achieving a balanced taste. It is worth noting that the concentration of each substance depends on its content in the coffee beans. This content depends, in turn, on the soil and other factors related to the growing conditions of the coffee tree.

Espresso preparation procedure

The technique for preparing espresso coffee includes the following steps:

• Roasting coffee beans.
• Grinding grains.
• Coffee dosage.
• Pouring ground coffee into the portafilter basket.
• Tamping coffee in a portafilter. This step also includes breaking up any clumps and leveling the coffee inside the portafilter basket.
• Pre-wetting, which is only possible in some espresso coffee makers.
• Espresso coffee extraction. In English, this process is also called pulling, since in early manual espresso machines the barista pulled the handle to get a shot of espresso.

In this article we will reverse Special attention the pressure-based steps of espresso preparation, including tamping, pre-wetting, and brewing.

Tamping

When preparing a shot of espresso, pressurized water is forced through a portafilter. In this case, substances are extracted from ground coffee that give the drink its properties and taste. If the coffee tablet in the portafilter is not compacted uniformly, water will flow through the points of least resistance. The coffee at these points will be over-extracted, while at other points it will be under-extracted. This will have a bad effect on the taste of the coffee. To avoid this problem, the lumps in the coffee are loosened and then tamped or, as they now say, tamped with a special device called a tamper.

There are several ways to get rid of the areas of least resistance in your ground coffee. One method called Weiss distribution technique, is used to break up lumps caused by the oils that coffee releases during grinding. They do this as follows:

• Add coffee to portafilter;
• Use a makeshift funnel for the portafilter basket to prevent the coffee from spilling out when stirring. To do this, you can attach a yogurt cup or a plastic juice bottle with the bottom cut off to the portafilter;
• Stir the ground coffee well with a thin stick, such as a chopstick or a thin wooden skewer;
• Tap the edges of the plastic nozzle to release all the coffee back into the portafilter basket.
• The next step is the compaction itself.

Tamping is the process of uniform compaction of a coffee tablet. The pressure exerted by the tamper on the ground coffee must be sufficient to form a dense tablet that traps the flow of pressurized water. What exactly the pressure should be is usually determined by experimenting with different sizes pressure. You can first try the recommended values ​​for pressure, and then experiment, observing how changes in pressure affect the taste of the finished drink, and in what concentrations each component is extracted at a certain pressure. Typically, the literature for espresso coffee lovers recommends the following:

• Start tamping the coffee, applying about 2 kg of pressure.
• Continue compacting using 14 kg of pressure.

Some experts recommend first using a scale or a tamper with a dynamometer (professional, read: expensive solution) in order to know for sure that the tamping was done at the correct pressure, and to feel with what force the tamping should be done. To apply even pressure across the surface of the coffee tablet, it is important to use a tamper that is the same diameter as the portafilter basket. It is usually difficult to tamp coffee neatly using the standard plastic tamper that comes with some espresso machines, as it is difficult to keep perpendicular to the surface of the coffee, and often its diameter is too small and the pressure is uneven. It is best to use a metal tamper whose diameter is only slightly less than diameter filter.

Pressure in espresso coffee makers

As their name suggests, espresso coffee makers are designed specifically for making espresso coffee. There are many ways to extract the different aromatics from coffee beans to make this drink, from cooking on the stovetop in a pot or drip coffee maker, to using pressurized hot water through a coffee pod like an espresso maker. The pressure in coffee makers is very great importance. More expensive coffee makers are equipped with pressure meters (pressure gauges), and in coffee makers without pressure gauges, amateurs often install homemade pressure gauges.

To make delicious espresso, you need to extract enough solids and aromatic oils through extraction (otherwise the coffee will be watery and sour), but it's important not to overdo it (or the coffee will turn out too bitter). How much parameters such as temperature and pressure affect the taste of the final product depends on the quality of the coffee beans and how well they are roasted. The espresso technique tends to extract more acids from light roasts, so dark roasts are typically used for espresso. Light roasts are more often used in drip coffee makers.

Typically, both home and commercial coffee makers use a pressure of 9-10 bar. One bar is equal to atmospheric pressure at sea level. Some experts advise varying the pressure during cooking. Italian national institute espresso advises using a pressure of about 9±1 bar or 131±15 psi.

Parameters affecting coffee preparation

Although in this article we are mainly talking about pressure, it is worth mentioning other parameters that also affect the taste of the finished coffee. We will also discuss how the choice of these parameters depends on the coffee preparation method.

Temperature

The coffee preparation temperature varies between 85–93 °C, depending on the preparation method. If this temperature is lower than it should be, the aromatic components are not extracted in sufficient quantities. If the temperature is higher than necessary, the bitter components are extracted. Temperature in espresso coffee makers is usually not adjustable and cannot be changed, but you should be careful with the temperature when using other brewing methods, especially those that can easily overheat the coffee.

Grinding

Pre-wetting

Some high-end espresso makers have the option of pre-wetting the ground coffee while brewing. This mode is used because it is believed that increasing the time the coffee is in contact with water improves the flavor and aroma during extraction. Of course, we could simply increase the time the water passes through the portafilter. This will increase the amount of water that flows through the portafilter, but this will result in a decrease in coffee concentration since the amount of ground coffee remains the same. On the other hand, during the pre-wet process, which occurs at low pressure, the amount of water does not increase much, but the water remains in contact with the coffee longer, which improves the taste of the finished drink.

Cooking time

When preparing espresso, it is very important to choose the right time so as not to overcook or undercook the coffee. You can navigate by the following parameters:

• Find the optimal color where you like the taste of coffee the most. To do this, you can experiment by stopping the extraction at different stages until you make coffee that you like.
• Measure how long it takes to brew coffee of that color. This time should be between 25 and 35 seconds, and if it is different, then you need to change the grind.
• If the time is less than 25 seconds, then the grind is too coarse and needs to be finer.
• If the time is more than 35 seconds, then the grind, on the contrary, is too fine and needs to be made coarser.

Do you find it difficult to translate units of measurement from one language to another? Colleagues are ready to help you. Post a question in TCTerms and within a few minutes you will receive an answer.

Instructions

Recalculate the original pressure value (Pa), if it is given in megapascals (mPa). As you know, there are 1,000,000 pascals in one megapascal. Let's say you need to convert to 3 megapascals, it will be: 3 mPa * 1,000,000 = 3,000,000 Pa.

Solution: 1 Pa = 0001 Pa = 0.001 kPa.

Answer: 0.001 kPa.

When solving physical problems, keep in mind that pressure can be specified in other pressure units. Especially often when measuring pressure one encounters a unit such as N/m² (per square meter). In fact, this unit is equivalent to the pascal, as it is its definition.

Formally, the unit of pressure pascal (N/m²) is also equivalent to the unit of energy density (J/m³). However, from a physical point of view, these units describe different. Therefore, do not write the pressure as J/m³.

If the problem conditions involve many other physical quantities, then convert pascals to kilopascals at the end of solving the problem. The fact is that this is a system unit and, if the other parameters are indicated in SI units, then the answer will be in pascals (of course, if the pressure was determined).

Sources:

• Kilopascal, Pressure
• how to translate kpa

Pascals measure the pressure that is exerted by a force F on a surface whose area is S. In other words, 1 Pascal (1 Pa) is the magnitude of the effect of a force of 1 Newton (1 N) on an area of ​​1 m². But there are other units for measuring pressure, one of which is megapascal. So how do you convert megapascals?

You will need

• Calculator.

Instructions

First you need to understand those units of pressure that are between pascal and megapascal. 1 (MPa) contains 1000 Kilopascals (KPa), 10000 Hectopascals (GPa), 1000000 Decapascals (DaPa) and 10000000 Pascals. This means that in order to convert , you need to raise 10 Pa to the power “6” or multiply 1 Pa by 10 seven times.

In the first step, it became clear that the direct action was to move from small pressure units to larger ones. Now, to do the opposite, you will need to multiply the existing value in megapascals by 10 seven times. In other words, 1 MPa = 10,000,000 Pa.

For simplicity and clarity, we can consider: in an industrial propane cylinder the pressure is 9.4 MPa. How many Pascals will this same pressure be?
The solution to this problem requires the above method: 9.4 MPa * 10000000 = 94000000 Pa. (94 Pascals).
Answer: in an industrial cylinder the pressure on its walls is 94,000,000 Pa.

Video on the topic

note

It is worth noting that much more often it is not the classical unit of pressure that is used, but the so-called “atmosphere” (atm). 1 atm = 0.1 MPa and 1 MPa = 10 atm. For the example discussed above, another answer will be valid: the propane pressure of the cylinder wall is 94 atm.

It is also possible to use other units, such as:
- 1 bar = 100000 Pa
- 1 mmHg (millimeter of mercury) = 133.332 Pa
- 1 m of water. Art. (meter of water column) = 9806.65 Pa

Helpful advice

Pressure is denoted by the letter P. Based on the information given above, the formula for finding pressure will look like this:
P = F/S, where F is the force on the area S.
Pascal is a unit of measurement used in the SI system. In the CGS system ("Centimeter-Gram-Second"), pressure is measured in g/(cm*s²).

Sources:

• how to convert from megapascals to pascals

More precisely, in kilogram-force, force is measured in the MKGSS system (abbreviation for “Meter, KiloGram-Force, Second”). This set of standards for units of measurement is rarely used today, as it has been supplanted by another international system - SI. It uses a different unit for measuring force, called Newtons, so sometimes you have to resort to converting values ​​from kilogram-force to Newtons and their derivatives.

The principle of operation of many modern hydraulic devices - lifts, brakes, presses, water supply systems - is explained on the basis of Pascal's law. In 1961, one of the SI units was named after this scientist, who made a great contribution to the development of physics, mathematics, philosophy and other sciences. What is measured in pascals?

Pascal

So, pascal (Pa) is a measure of pressure, mechanical stress, elastic modulus and some other characteristics used in technology. A pressure of 1 pascal is created by a force of 1 newton, uniformly distributed over an area of ​​1 square meter perpendicular to the direction of its action (1 Pa = 1 N/m2). Remembering that 1 N = 1 kg∙m/s 2, we can express the pascal in terms of SI base units: 1 Pa = 1 kg/(m∙s 2).

Pressure is a scalar quantity; it characterizes the result of the action of an external force on a surface distributed over its area. Let's explain this with an example: imagine a person who first moves through loose snow on skis, and then takes them off and falls deep into a snowdrift. In the first case, the force - the weight of a person - is evenly distributed over a relatively large surface of the skis, in the other - only over the area of ​​​​the foot, which leads to an increase in pressure, and consequently to subsidence of the snow.

External forces acting on a body tend to shift the position of the particles of which it consists. In response to this, inside the body there will be internal forces, preventing displacement. The measure of the result of their action is called mechanical stress, which is also expressed in pascals.

What else is used to measure blood pressure?

If we're talking about about pressure in medicine or meteorology, it is more often estimated in other units - millimeters of mercury. And in technology you can find such pressure measures as bar or atmosphere. Therefore, it is important to be able to convert them to pascals.

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