How to choose a solid fuel boiler by power

In order to choose a solid fuel boiler, you need to pay attention to the power. This parameter shows how much heat a specific device can create when connected to the heating system. It directly depends on this whether it is possible with the help of such equipment to provide the house with heat in the required amount or not.

For example, in a room where a low-power pellet boiler is installed, it will be cool at best. Also, it is not the best option to install a boiler with excess capacity, because it will constantly work in an economical mode, and this will significantly reduce the efficiency indicator.

So, in order to calculate the power of the boiler for heating a private house, you need to follow certain rules.

How to calculate the power of a heating boiler, knowing the volume of the heated room?

The heat output of the boiler is determined by the formula:

Q = V × ΔT × K / 850

• Q
  - the amount of heat in kW / h
• V
  - the volume of the heated room in cubic meters
• ΔT
  - the difference between the temperature outside and inside the house
• TO
  - coefficient of heat loss
• 850
  - the number due to which the product of the above three parameters can be converted into kW / h

Indicator TO

can have the following meanings:

• 3-4 - if the structure of the building is simplified and wooden, or if it is made of profiled sheet
• 2-2.9 - the room has little thermal insulation. Such a room has a simple structure, the length of 1 brick is equal to the thickness of the wall, the windows and the roof have a simplified construction.
• 1-1.9 - the building structure is considered standard. These houses have a double brick tab and few simple windows. Roof roof ordinary
• 0.6-0.9 - the structure of the building is considered to be improved. Such a building has double glazed windows, the base of the floor is thick, the walls are brick and have double thermal insulation, the roof has thermal insulation made of good material.

Below is a situation in which a heating boiler is selected according to the volume of the heated room.

The house has an area of ​​200 m², the height of its walls is 3 m, and the thermal insulation is first class. The ambient temperature near the house does not fall below -25 ° C. It turns out that ΔT = 20 - (-25) = 45 ° C. It turns out that in order to find out the amount of heat that is required to heat a house, you need to make the following calculation:

Q = 200 × 3 × 45 × 0.9 / 850 = 28.58 kWh

The result obtained should not yet be rounded off, because a hot water supply system can still be connected to the boiler.

If the water for washing is heated in a different way, then the result that was obtained independently does not need to be adjusted and this stage of the calculation is final.

Objective parameters for power calculation

To calculate how much power the equipment should be, it is necessary to take into account the mass of parameters. Almost all of them have a mathematical expression and participate in a formula that gives accurate indicators of the power of solid fuel boilers.

The parameters to be considered include:

1. Room volume
   (V cubic meter). Surely you know the area of ​​your house and the height of the ceilings.
2. Difference t ° С
   between the desired home and expected outdoor in the coldest period and (ΔT ° C). It is calculated individually based on your preferences and the climate of the region:

• want 22 ° С in the house - (- 28 February degrees) = 50 ° С. It is this indicator that will need to be substituted into the main calculation formula, which we will give below.

• Heat coefficient
  , which is lost for various reasons (K). Generally accepted values ​​determined empirically. Choose from the list that is suitable for your home:
• 3-4 - a wooden country house without additional insulation (brick or foam);
• 2-2.9 - a wooden building with thermal insulation or a house with one-brick walls, and single-glass windows;
• 1-1.9 - a structure with walls of two bricks, double glazed windows and a roof without insulation;
• 0.6-0.9 - modern construction option: double glazed windows, thermal insulation of walls, roof and floor.

The number that allows you to convert the resulting figure in kW - 850
.

As you can see, only two quantities need to be calculated: the internal volume of the house and the temperature difference. The rest of the indicators are ready for use. Now we can determine the main indicator - the boiler power (Q kW / h).

Formula for calculating the power of the boiler

Find out the above parameters, and all that remains is to substitute them into the formula:

V * ΔT * K / 850 = Q

For example, you have a house built in the late 90s with an area of ​​150 sq. M and ceilings of 3 m (volume = 450). And consider a comfortable temperature of 22 degrees (the difference is calculated above). Then your definition of the boiler power will look like this:

450 * 50 * 1/850 = 26.47 kWh

This indicator can be final if there are no other factors, for example, the use of part of the heat for heating water, floor heating. Otherwise, you will need to choose a boiler for heating with a higher power than the calculated one.

There is also a simpler calculation, but less accurate. You don't even need complex calculations. It is generally accepted that for 10 square meters of area, 1.3 kW of heating boiler power is needed. Therefore, with the same area of ​​150, you can draw up the following formula:

150 * 1.3 / 10 = 19.5 kWh

As you can see, the difference with more complex calculations is almost 7 kW. Of course, it is your right to determine for yourself what required power is considered correct and to buy a solid fuel boiler, based on your own conclusions.

If you are sure that the winter will be mild, or are working on first-class insulation of the house, then you can calculate the power of the heating boiler in a simplified way. If you just want to save money by buying thermal equipment of lower power, then you risk getting no more than 15 ° С in the house.

The formula for calculating the power of the boiler with connection to the boiler

Often store consultants recommend adding another 30% to the capacity of the equipment. Therefore, it is necessary to buy a solid fuel boiler with a capacity of 34.4 kW / h (26.47 + 30%). How true is this? Below we give the calculation of the objective kW for water heating.

Qw = s * m * Δt

In this formula, as in calculating the boiler power only for heating, understandable to everyone are used indicators

:

• constant of heat capacity of water (4200 J / kg * K) - s;
• mass of water that requires heating (kg) - m;
• the difference in t ° C of water in the water supply system and the boiler.

We take as an example the same house with heating with a 26.47 kW boiler. It is to this indicator that we will add a new one.

One indicator we have is unchanged (c). Water volume: a family of 2 consumes an average of 400 kg of water per day (with a bathtub installed). This figure can be significantly lower if the bath is not filled every day. However, we will take a larger one to understand the possible needs of your family, i.e. exactly 400 kg.

The temperature difference is easy to calculate. The water temperature in the boiler is usually 80 ° C. Residual water in water supply pipes - 10-12 ° С. Accordingly, the difference is 68 degrees.

Payment:

4200 * 400 * 68 = 114240000 J / kg * K

We translate into kW = 31.73

As you can see, the indicator is not quite 30%. And you need a heating boiler of 68.2 kW (26.47 + 31.73). However, as already mentioned, the maximum water flow rate is taken. Perhaps with less, a 30% increase in the indicator will be enough.

Conclusion from the above example! Do not rely on the advice of someone who does not know your family's hot water needs.

How to calculate how much heat is needed to heat water?

To calculate the heat consumption in this case, it is necessary to independently add the heat consumption for hot water supply to the previous indicator. To calculate it, you can use the following formula:

Qw = s × m × Δt

• from
  - specific heat capacity of water, which is always equal to 4200 J / kg K,
• m
  - mass of water in kg
• Δt
  - the difference in temperature between the heated water and the incoming water from the water supply.

For example, the average family consumes 150 liters of warm water on average. The coolant that heats the boiler has a temperature of 80 ° C, and the temperature of the water coming from the water supply is 10 ° C, then Δt = 80 - 10 = 70 ° C.

Hence:

Qw = 4200 × 150 × 70 = 44,100,000 J or 12.25 kW / h

Then you need to do the following:

1. Suppose you need to heat 150 liters of water at a time, which means that the capacity of the indirect heat exchanger is 150 liters, therefore, 12.25 kW / h must be added to 28.58 kW / h. This is done because the Qzag indicator is less than 40.83, therefore, the room will be cooler than the expected 20 ° C.
2. If the water is heated in portions, that is, the capacity of the indirect heat exchanger is 50 liters, the indicator 12.25 must be divided by 3 and then added independently to 28.58. After these calculations, Qzag is equal to 32.67 kW / h. The resulting indicator is the power of the boiler, which is needed to heat the room.

Calculation of the power of electric boilers

Electric boilers for heating private houses have the following features:

• high cost of fuel, in this case electricity;
• environmental friendliness;
• Ease of Management;
• the occurrence of problems with the functioning due to possible outages in the network;
• compact parameters.

All these nuances should be taken into account when calculating the power of an electric heating boiler, since it must function reliably and efficiently for a long time.

Selection of a boiler by the area of ​​a private house. How to make a calculation?

This calculation is more accurate because it takes into account a huge number of nuances. It is produced according to the following formula:

Q = 0.1 × S × k1 × k2 × k3 × k4 × k5 × k6 × k7

1. 0.1 kW
   - the rate of required heat per 1 m².
2. S
   - the area of ​​the room to be heated.
3. k1
   shows the heat that was lost due to the structure of the windows, and has the following indicators:

• 1.27 - single glass by the window
• 1.00 - double-glazed window
• 0.85 - triple glass by the window

1. k2
   shows the heat that has been lost due to the area of ​​the window (Sw). Sw refers to the floor area Sf. Its indicators are as follows:

• 0.8 - at Sw / Sf = 0.1;
• 0.9 - at Sw / Sf = 0.2;
• 1.0 - at Sw / Sf = 0.3;
• 1.1 - at Sw / Sf = 0.4;
• 1.2 - at Sw / Sf = 0.5.

1. k3
   shows heat leakage through walls. Can be as follows:

• 1.27 - poor-quality thermal insulation
• 1 - the wall of the house is 2 bricks thick or insulation 15 cm thick
• 0.854 - good thermal insulation

1. k4
   shows the amount of heat lost due to the temperature outside the building. Has the following indicators:

• 0.7, when tz = -10 ° C;
• 0.9 for tz = -15 ° C;
• 1.1 for tz = -20 ° C;
• 1.3 for tz = -25 ° C;
• 1.5 for tz = -30 ° C.

1. k5
   shows how much heat is lost due to the outer walls. Has the following meanings:

• 1.1 in the building 1 outer wall
• 1.2 in the building 2 external walls
• 1.3 in the building 3 external walls
• 1.4 in the building 4 outer walls

1. k6
   shows the amount of heat that is needed additionally and depends on the height of the ceiling (H):

• 1 - for a ceiling height of 2.5 m;
• 1.05 - for a ceiling height of 3.0 m;
• 1.1 - for a ceiling height of 3.5 m;
• 1.15 - for a ceiling height of 4.0 m;
• 1.2 - for a ceiling height of 4.5 m.

1. k7
   shows how much heat has been lost. Depends on the type of building that is located above the heated room. Has the following indicators:

• 0.8 heated room;
• 0.9 warm attic;
• 1 cold attic.

As an example, we will take the same initial conditions, except for the parameter of windows, which have a triple glass unit and make up 30% of the floor area. The structure has 4 exterior walls and a cold attic above it.

Then the calculation will look like this:

Q = 0.1 x 200 x 0.85 x 1 x 0.854 x 1.3 x 1.4 x 1.05 x 1 = 27.74 kWh

This indicator must be increased, for this you need to independently add the amount of heat that is required for DHW if it is connected to the boiler.

If you do not need to perform accurate calculations, then you can use a universal table.With it, you can determine the power of the boiler by the area of ​​the house. For example, a boiler with a capacity of 19 kW is suitable for heating a room of 150 square meters, and 200 square meters for heating. will require 22 kW.

Option	House area, sq.m.	Heating, kW	Number of devices	Number of people	DHW boiler, l / kW
1	150	19	10	4	100/28
2	200	22	11	4	100/28
3	250	25,5	17	4	160/33
4	300	27	20	6	160/33
5	350	31	26	6	200/33
6	400	34	30	6	200/33
7	450	36	44	6	300/36

The above methods are very useful to calculate the boiler capacity for heating a house.

Example of calculating the boiler output

An illustrative example will show how to calculate the boiler power for a house and the rate of heat transfer. The initial data are as follows: the area of ​​the heated premises in the house is 100m²; the building is located in the Moscow region (Wsp. is 1.2 kW). If you substitute these values ​​into the formula, the result will look like this: Boiler W = (100x1.2) / 10 = 12 kW (in more detail: "Correct calculation of the heat output of the heating system by the area of ​​the room").

Calculation of the real power of a long-burning boiler using the example of "Kupper PRACTIC-8"

The design of most boilers is designed for the specific type of fuel on which this device will operate. If a different category of fuel is used for the boiler, which is not reassigned for it, the efficiency will be significantly reduced. It is also necessary to remember about the possible consequences of using the fuel that is not provided by the manufacturer of the boiler equipment.

Now we will demonstrate the calculation process using the example of the Teplodar boiler, the Kupper PRACTIC-8 model. This equipment is intended for the heating system of residential buildings and other premises, which have an area of ​​less than 80 m². Also, this boiler is universal and can work not only in closed heating systems, but also in open ones with forced circulation of the coolant. This boiler has the following technical characteristics:

1. the ability to use firewood as fuel;
2. on average per hour, he burns 10 firewood;
3. the power of this boiler is 80 kW;
4. the loading chamber has a volume of 300 liters;
5. The efficiency is 85%.

Suppose that the owner uses aspen wood as fuel to heat the room. 1 kg of this type of firewood gives 2.82 kWh. For one hour, the boiler consumes 15 kg of firewood, therefore, it produces heat 2.82 × 15 × 0.87 = 36.801 kWh of heat (0.87 is the efficiency).

This equipment is not enough for heating a room that has a heat exchanger with a volume of 150 liters, but if the DHW has a heat exchanger with a volume of 50 liters, then the capacity of this boiler will be quite enough. In order to get the desired result of 32.67 kW / h, you need to spend 13.31 kg of aspen firewood. We make the calculation using the formula (32.67 / (2.82 × 0.87) = 13.31). In this case, the required heat was determined by the volume calculation method.

You can also make an independent calculation and find out the time it takes for the boiler to burn all the firewood. 1 liter of aspen wood has a weight of 0.143 kg. Therefore, the loading compartment will fit 294 × 0.143 = 42 kg of firewood. That much wood will be enough to keep warm for more than 3 hours. This is too short a time, therefore, in this case, it is necessary to find a boiler with a furnace size 2 times larger.

You can also look for a fuel boiler that is designed for several types of fuel. For example, a boiler from the same, only the Kupper PRO-22 model, which can work not only on wood, but also on coals. In this case, when using different types of fuel, there will be different power. The calculation is carried out independently, taking into account the efficiency of each type of fuel separately, and later the best option is selected.

Calculation of the power of solid fuel boilers

Solid fuel devices have a number of features:

• insignificant popularity;
• availability;
• the ability to function offline, which is provided in modern models;
• inexpensive operation;
• the need to have a utility room for storing fuel.

When calculating the heating power using a solid fuel boiler, it should be borne in mind that during the day the temperature in the room will vary within 5 degrees. For this reason, such a heating structure does not belong to the best choice and, if possible, it is advisable to refuse it.
When there is no other option for the heating system, there are two ways how to level the existing disadvantages:

• use a thermal bulb to regulate the air supply, which makes it possible to make the fuel burning time longer and reduce the number of furnaces;
• use water heat accumulators that are connected to the heating system. This allows you to reduce energy costs, which means fuel savings.

As a result of the measures taken, the performance of a solid fuel unit for heating a private household will be reduced. The effect of them must be taken into account when it is required to calculate the power of the heating boiler and the entire heating system.