How to find out where the return flow is in the heating system?

What should be the operating pressure in the heating system

But to answer this question in a nutshell is quite simple. Much depends on which house you live in. For example, for an autonomous or apartment, 0.7-1.5 atm is often considered normal. But again, these are approximate figures, since one boiler is designed to operate in a wider range, for example, 0.5-2.0 atm, and the other in a smaller one. This must be seen in the passport of your boiler. If there is none, stick to the golden mean - 1.5 Atm. The situation is quite different in those houses that are connected to central heating. In this case, it is necessary to be guided by the number of storeys. In 9-storey buildings, the ideal pressure is 5-7 atm, and in high-rise buildings - 7-10 atm. As for the pressure under which the carrier is supplied to the buildings, it is most often 12 atm. You can lower the pressure using pressure regulators, and increase it by installing a circulation pump. The latter option is extremely relevant for the upper floors of high-rise buildings.

The advantage of using automatic balance valves is also the possibility of dividing the system into separate pressure-independent zones and their phased commissioning. The advantages of automatic balance valves include easier and faster system setup, fewer valves and minimal system maintenance. Modern automatic balance valves are characterized by high reliability and improved control characteristics. Some of them are modular as a design, that is, they can be updated or expanded in functionality.

Features of supply in the heating system

Heat supply comes directly from the boiler, the liquid is carried along the batteries from the main element - the boiler (or the central system). It is typical for one-pipe systems. If it is improved, then it is possible to insert pipes into the return line as well.

Photo 1. Heating scheme for a private two-story house with an indication of the supply and return pipes.

Where is the return line

In short, the heating circuit consists of several important elements: a heating boiler, batteries and an expansion tank. In order for the heat to flow through the radiators, a coolant is needed: water or antifreeze. With a competent construction of the circuit, the coolant heats up in the boiler, rises through the pipes, increasing its volume, and all the excess enters the expansion tank.

Based on the fact that the batteries are filled with liquid, hot water displaces cold water, which, in turn, enters the boiler again for subsequent heating. Gradually, the degree of water increases and reaches the desired temperature. In this case, the circulation of the coolant can be natural or gravitational, carried out using pumps.

Based on this, the coolant can be considered the return flow, which went through the entire circuit, giving off heat, and already cooled down again entered the boiler for subsequent heating.

Principle of operation

The principle of operation of a one-pipe system is that hot water is supplied from the boiler and goes sequentially from one radiator to another, gradually cooling down. Thus, in the outer rooms, at the end of the chain, the batteries will produce less heat. If this system is slightly improved so that two pipes cut into the passing pipe from each radiator - one with supply, the other with return, and thermo-ventilators were installed on each radiator, then it will be warmer in the outer rooms. The two-pipe system is more thoughtful - two pipes are connected in parallel (supply and return). Slightly cooled water leaves through the second pipe, which is located at a slight slope towards the boiler.

Pressure regulator

The operation of the batteries and the pump is impaired due to high or low pressure levels.Correct control in the heating system will help to avoid this negative factor. The pressure in the system plays a significant role, it ensures that water enters the pipes and radiators. Heat loss will be reduced if the pressure is standardized and maintained. This is where water pressure regulators come to the rescue. Their mission is, first of all, to protect the system from too much pressure. The principle of operation of this device is based on the fact that the valve of the heating system, located in the regulator, acts as an equalizer of efforts. Regulators are classified according to the type of pressure: statistical, dynamic. The choice of pressure regulator should be based on the capacity. This is the ability to pass the required volume of the coolant, in the presence of the required constant pressure drop.

Autonomous circuit pressure

The vivid meaning of the word "drop" is a change in level, a fall. Within the framework of the article, we will touch on it as well. So, what causes the pressure in the heating system to drop if it is a closed loop?

First, let's find it in memory: water is virtually incompressible.

Overpressure in the circuit is created by two factors:

• The presence of a diaphragm expansion tank with its air cushion in the system.

• heating radiators and pipe elasticity. Their elasticity tries to zero, but with a large area of ​​the inner surface of the contour, this factor also affects the internal pressure.

From a practical point of view, this indicates that the pressure drop in the heating system recorded by the pressure gauge in most cases is caused by a very small transformation of the volume of the circuit or a decrease in the amount of coolant.

And here is a likely list of both:

• When heated, polypropylene expands more strongly than water. When starting up a heating system assembled from polypropylene, the pressure in it may drop slightly.
• Many materials (as well as aluminum) are flexible enough to change their shape under long exposure to moderate pressures. Aluminum radiators can simply swell over time.
• The gases dissolved in the water slowly leave the circuit through the air vent, affecting the actual amount of water in it.
• Large heating of the coolant with an underestimated volume of the expansion tank of the heating can lead to the operation of the safety valve.

Finally, real malfunctions cannot be ruled out in full: minor leaks along the weld seams and the joints of the sections, the etching nipple of microcracks and the expansion tank in the boiler heat exchanger.

Working pressure in the heating system

The working pressure is the pressure, the value of which ensures the optimal operation of all heating equipment (including the heating source, pump, expansion tank). In this case, it is taken equal to the sum of the pressures:

• static - created by a column of water in the system (in the calculations, the ratio is taken: 1 atmosphere (0.1 MPa) per 10 meters);
• dynamic - due to the operation of the circulation pump and the convective movement of the coolant when it is heated.

It is clear that in different heating schemes the value of the working head will differ. So, if the natural circulation of the coolant is provided for the heating of the house (applicable for individual low-rise construction), its value will exceed the static indicator by only a small amount. In compulsory schemes, however, it is taken as the maximum permissible to ensure a higher efficiency.

Numerically, the value of the working head is:

• for one-storey buildings with an open circuit and natural water circulation - 0.1 MPa (1 atmosphere) for every 10 m of the liquid column;
• for low-rise buildings with a closed circuit - 0.2-0.4 MPa;
• for multi-storey buildings - up to 1 MPa.

Features of supply in the heating system

Heat supply comes directly from the boiler, the liquid is carried along the batteries from the main element - the boiler (or the central system). It is typical for one-pipe systems. If it is improved, then it is possible to insert pipes into the return line as well.

Photo 1. Heating scheme for a private two-story house with an indication of the supply and return pipes.

Safety valves

Any boiler equipment is a source of danger. The boilers are considered explosive because they have a water jacket, i.e. pressure vessel. One of the most reliable and common safety devices that minimizes danger is the heating system safety valve. The installation of this device is due to the protection of heating systems from overpressure. Often, this pressure occurs as a result of boiling water in the boiler. The safety valve is installed on the supply pipe, as close as possible to the boiler. The valve has a fairly simple design. The body is made of good quality brass. The main working element of the valve is the spring. The spring, in turn, acts on the membrane, which closes the passage to the outside. The diaphragm is made of polymer materials, the spring is made of steel. When choosing a safety valve, it should be borne in mind that full opening occurs when the pressure in the heating system rises above the value by 10%, and full closure when the pressure drops below the response by 20%. Due to these characteristics, it is necessary to select a valve with a response pressure higher than 20-30% of the actual one.

Features of the heating system of apartment buildings

When equipping heating in multi-storey buildings, it is imperative to comply with the requirements established by regulatory documents, which include SNiP and GOST. These documents indicate that the heating structure should provide a constant temperature in apartments within the range of 20-22 degrees, and the humidity should vary from 30 to 45 percent.

To achieve the required parameters, a complex design is used that requires high-quality equipment. When creating a project for a heating system for an apartment building, specialists use all their knowledge to achieve an even distribution of heat in all sections of the heating main and create a comparable pressure on each tier of the building. One of the integral elements of the work of such a structure is work on an overheated coolant, which provides for a heating scheme for a three-story building or other high-rise buildings.

How it works? The water comes directly from the CHP and is heated up to 130-150 degrees. In addition, the pressure is increased to 6-10 atmospheres, so the formation of steam is impossible - high pressure will drive water through all floors of the house without loss. In this case, the temperature of the liquid in the return pipe can reach 60-70 degrees. Of course, at different times of the year, the temperature regime can change, since it is directly tied to the ambient temperature.

Methods for organizing the heating system

A heating system with a return pipe can be organized in several ways:

1. Water supply from the top: under the roof of the building, in the attic or on those floors. A pipeline check valve, on the other hand, is located at the bottom of the house: under the floor or in the basement. The reverse design is also provided: the supply is at the bottom, and the exit is at the top of the house.
2. The supply and return water pipe runs inside the basement.

In modern new buildings, heating and water supply is arranged according to the principle of continuous fluid functioning along the contours. This ensures a constant temperature of the pipes in the building and rapid heating of the liquid during withdrawal.

Heating system

Design features of the heating circuit

In modern buildings, additional elements are often used, such as collectors, heat meters for batteries and other equipment. In recent years, almost every heating system in high-rise buildings has been equipped with automation in order to minimize human intervention in the work of the structure (read: "Weather-dependent automation of heating systems - about automation and controllers for boilers by examples"). All the details described allow you to achieve better performance, increase efficiency and make it possible to more evenly distribute heat energy across all apartments.

Types of heating systems

The amount of heat that a heating radiator will emit depends not least on the type of heating system and the selected type of connection. To choose the best option, you must first figure out what kind of heating systems are and how they differ.

Single pipe

A single pipe heating system is the most economical option in terms of installation costs. Therefore, it is this type of wiring that is preferred in multi-storey buildings, although in private such a system is far from uncommon. With this scheme, the radiators are connected to the line in series and the coolant first passes through one heating part, then enters the inlet of the second, and so on. The output of the last radiator is connected to the input of the heating boiler or to the riser in high-rise buildings.

Example of a one-pipe system

The disadvantage of this wiring method is the impossibility of adjusting the heat transfer of the radiators. By installing a regulator on any of the radiators, you will regulate the rest of the system. The second significant drawback is the different temperature of the coolant for different radiators. Those that are closer to the boiler heat up very well, those farther - get colder. This is a consequence of the serial connection of heating radiators.

Two-pipe wiring

The two-pipe heating system differs in that it has two pipelines - supply and return. Each radiator is connected to both, that is, it turns out that all radiators are connected to the system in parallel. This is good because a coolant of the same temperature is supplied to the input of each of them. The second positive point is that a thermostat can be installed on each of the radiators and with its help you can change the amount of heat that it emits.

The disadvantage of such a system is that the number of pipes in the wiring of the system is almost twice as large. But the system can be easily balanced.

Briefly about the return and supply in the heating system

The hot water heating system, using the supply from the boiler, supplies the heated coolant to the batteries that are located inside the building. This makes it possible to distribute heat throughout the house. Then the coolant, that is, water or antifreeze, passing through all the available radiators, loses its temperature and is fed back for heating.

The most straightforward heating structure is a heater, two lines, an expansion tank and a set of radiators. The water conduit through which the heated water from the heater moves to the batteries is called supply. And the water conduit, which is located at the bottom of the radiators, where the water loses its original temperature, returns back, and will be called the return. Since water expands as it warms up, the system provides for a special tank. It solves two problems: water supply to saturate the system; takes in excess water that is obtained during expansion. Water, as a heat carrier, is directed from the boiler to the radiators and back. Its flow is provided by a pump, or natural circulation.

Supply and return are present in one and two pipe heating systems. But in the first, there is no clear distribution into the supply and return pipes, and the entire pipe line is conventionally divided in half.The column that leaves the boiler is called the feed, and the column leaving the last radiator is called the return.

In a single-pipe line, heated water from the boiler flows sequentially from one battery to another, losing its temperature. Therefore, at the very end, the batteries will be the coldest. This is the main and, probably, the only disadvantage of such a system.

But the single-pipe version will gain more advantages: lower costs are required for the acquisition of materials in comparison with the 2-pipe version; the diagram is more attractive. The pipe is easier to hide, and you can also lay pipes under doorways. The two-pipe system is more efficient - in parallel, two fittings are installed in the system (supply and return).

Such a system is considered by specialists to be more optimal. After all, her work stagnates on the supply of hot water through one pipe, and the chilled water is diverted in the opposite direction through another pipe. In this case, the radiators are connected in parallel, which ensures uniform heating. Which of them sets the approach should be individual, taking into account many different parameters.

There are only a few general tips to follow:

1. The entire line must be completely filled with water, air is an obstacle, if the pipes are airy, the quality of heating is poor.
2. A sufficiently high liquid circulation rate must be maintained.
3. The temperature difference between supply and return should be about 30 degrees.

How to fix the situation with a drop

Everything is extremely simple here. First, you need to take a look at the pressure gauge, which has several characteristic zones. If the arrow is in green, then everything is fine, and if it is noticed that the pressure in the heating system is dropping, then the indicator will be in the white zone. There is also a red one, it signals an increase. In most cases, you can handle it on your own. First, you need to find two valves. One of them serves for injection, the second - for bleeding the carrier from the system. Then everything is simple and clear. If there is a lack of media in the system, it is necessary to open the discharge valve and observe the pressure gauge installed on the boiler. When the arrow reaches the required value, close the valve. If bleeding is needed, everything is done in the same way, with the only difference being that you need to take a vessel with you, where the water from the system will drain. When the arrow of the pressure gauge shows the rate, turn on the valve. Often this is how the pressure drop in the heating system is "treated". For now, let's move on.

They are widely used in constant flow systems. The main advantage of manual balance valves is their low cost. As a major disadvantage, it can be noted that every change in the installation must rebuild the system, which is labor intensive and costly.

Automatic balance valves Automatic balance valves allow flexible changes in the parameters of the piping system depending on pressure fluctuations and the flow of the working medium. They are proportional controllers that maintain a constant differential pressure in the system and minimize disturbances caused by control valves. They are characterized by high performance, which allows them to maintain established hydraulic conditions in the systems, compensating for disturbances caused by the control valve.

What is the reason for the need to use return water supply systems?

Here a natural question arises: why use the return water supply at the enterprises at all? After all, fresh, cleaner water could be used for a new production cycle. The fact is that the use of this system is a forced measure, which enterprises agree to in order to make less emissions of polluted water into the environment.After all, this has a very serious impact on the ecological situation.

Especially high demand for fresh water from enterprises of the metalworking industry, as well as enterprises that are engaged in mechanical engineering. At such enterprises, water pollution with various heavy metals, as well as other elements hazardous to human health, is inevitable. Therefore, the return water supply system is simply necessary. In this case, the water is filtered for reuse, its discharge into wastewater is completely excluded.

Pressure rate

Efficient transfer and uniform distribution of the heat carrier, for the performance of the entire system with minimal heat loss, are possible at normal operating pressure in the pipelines.

The coolant pressure in the system is subdivided according to the mode of action into types:

• Static. The force of action of a stationary coolant per unit area.
• Dynamic. Force of action when moving.
• Ultimate head. Corresponds to the optimal value of the fluid pressure in the pipes and capable of maintaining the operation of all heating devices at a normal level.

According to SNiP, the optimal indicator is 8-9.5 atm, pressure drop to 5-5.5 atm. often leads to interruptions in heating.

For each particular house, the indicator of normal pressure is individual. Its value is influenced by factors:

• power of the pumping system supplying the coolant;
• pipeline diameter;
• remoteness of the premises from the boiler equipment;
• wear of parts;
• pressure.

Pressure control is possible with pressure gauges mounted directly into the pipeline.

Methods for organizing the return

Today, heating systems can be organized according to one of the types of pipe routing:

• one-pipe;
• two-pipe;
• hybrid.

The choice of this or that method will depend on a number of factors, such as: the number of storeys of the building, the requirements for the cost of the heating system, the type of coolant circulation, the parameters of the radiators, etc.

The most common is one-pipe scheme piping. In most cases, it is used to heat multi-storey buildings. Such a system is characterized by:

• low cost;
• ease of installation;
• vertical system with upper heating agent supply;
• sequential connection of heating radiators, and, consequently, the absence of a separate riser for the return, i.e. the coolant after passing through the first radiator enters the second, then the third, etc .;
• impossibility of regulating the intensity and uniformity of heating radiators;
• high pressure of the coolant in the system;
• a decrease in heat transfer with distance from the boiler or expansion tank.

Figure 7 - One-pipe heating system with upper heating medium supply

It should be noted that in order to increase the efficiency of one-pipe systems, it is possible to envisage the use of circular sediments or a device on each floor of bypasses.

“Bypass - (English bypass, literally - bypass) - a bypass parallel to a straight section of the pipeline, with shut-off or control pipeline valves or devices (for example, liquid or gas meters). Serves to control the technological process in case of malfunction of valves or devices installed on a direct pipeline, as well as when it is necessary to urgently replace them due to a malfunction without stopping the technological process. " (Big Encyclopedic Polytechnic Dictionary)

Another option for piping is two-pipe schemealso called a return heating system. This type is most often used for individual construction or luxury housing.

This system consists of two closed circuits, one of which is intended for supplying the coolant to the heating radiators connected in parallel, the second for its removal.The main advantages of the two-pipe scheme are:

• uniform heating of all devices, regardless of their distance from the heat source;
• the ability to regulate the intensity of heating or repair (replacement) of each of the radiators without affecting the operation of others.

The disadvantages include a rather complicated connection scheme and laborious installation.

Figure 8 - Two-pipe heating system

It should be borne in mind that if such a system does not provide for the use of a circular pump, slopes should be observed during installation (for supply from the boiler, for return to the boiler).

The third type of pipe routing is considered hybrid, which combines the characteristics of the systems described above. An example is a collector circuit, in which an individual branch of the wiring is organized from the riser of the general supply of the coolant at each level.

Diameter of pipes, as well as the degree of their wear

It must be remembered that the size of the pipe must also be taken into account. Often, residents set the diameter they need, which is almost always slightly larger than the standard sizes. This leads to the fact that the pressure in the system decreases slightly, which is due to the large amount of coolant that will fit into the system. Do not forget that in corner rooms the pressure in the pipes is always less, since this is the most distant point of the pipeline. The degree of wear of pipes and radiators also affects the pressure in the heating system of the house. As practice shows, the older the battery, the worse. Of course, not everyone can change them every 5-10 years, and it is inappropriate to do this, but from time to time it will not hurt to carry out prevention. If you are moving to a new place of residence and you know that the heating system there is old, then it is better to change it right away, so you will avoid many troubles.

Hydraulic balance of hot water supply systems. The hot water temperature in hot water systems drops significantly with low or no consumption. This leads to several problems: long waiting times for hot water, water overflow and the possibility of unwanted bacteria growing. To maintain the water temperature at the required level, it is usually a constant circulation of water in the systems, through a circulation pump and a circulation pipe. Maintaining the hydraulic balance in these systems is usually done with direct acting temperature controllers.

Watch the video film "Return water system":

However, this method of purifying and reusing water is not ideal and therefore has its drawbacks. And first of all, the point is the imperfection of the systems for treating such water. The fact is that water that has passed several production cycles becomes salted, which ultimately leads to a lot of problems in the process of its use. Corrosion appears on the equipment, and the quality of the coating deteriorates when metal or plastic is processed using water. Therefore, today we are constantly developing and looking for an effective water purification system that would extend the life of the liquid in production and make the return water supply even more profitable for enterprises.

Although this method is not unprofitable for enterprises, since it saves about 85-90% of the funds allocated for the purchase of water on water supply.

Where to install radiators

Traditionally, heating radiators are placed under windows and this is no coincidence. The rising flow of warm air cuts off the cold air that comes from the windows. In addition, warm air heats the glass, preventing condensation from forming on them. Only for this it is necessary that the radiator occupies at least 70% of the width of the window opening. This is the only way the window will not fog up.Therefore, when choosing the power of radiators, select it so that the width of the entire radiator is not less than a given value.

How to position a radiator under a window

In addition, it is necessary to correctly select the height of the radiator and the place for its placement under the window. It must be placed so that the distance to the floor is in the region of 8-12 cm. If it is lowered below, it will be inconvenient to clean, if raised higher, it will be cold for the feet. The distance to the window sill is also regulated - it should be 10-12 cm. In this case, warm air will freely go around the barrier - the window sill - and rise along the window glass.

And the last distance that must be maintained when connecting heating radiators is the distance to the wall. It should be 3-5 cm. In this case, ascending streams of warm air will rise along the rear wall of the radiator, the heating rate of the room will improve.

About Leak Testing

It is imperative to check the system for leaks. This is done to ensure that the heating is efficient and does not fail. In multi-storey buildings with central heating, the cold water test is most often used. In this case, if the heating system drops by more than 0.06 MPa in 30 minutes or 0.02 MPa is lost in 120 minutes, it is necessary to look for places of gusts. If the indicators do not go beyond the norm, then you can start the system and start the heating season. The hot water test is carried out just before the heating season. In this case, the carrier is supplied under pressure, which is the maximum for the equipment.

Their goal is to maintain temperature and minimize water consumption in hot water circulation systems.

An important feature of these valves is the presence of periodic disinfection of the DHW pipeline network. Tags: balancing valves Manual balancing valves

Autonomous heating systems

Today you may not ask for cold, but your heating system will do it for you. If you haven't paid enough attention during the summer season, an unpleasant surprise can be expected at the beginning or during the heating season. Do you have a home in the cold because your radiators are no worse than ever before? A maintenance error or poor tuning of some parts of your heating system could be a malfunction. The summer months are best used to maintain their heating system, but many people will only start taking care of them when they need to flood for the first time.

Monitoring the operating pressure in heating circuits

For the normal trouble-free functioning of the heat supply system, it is necessary to regularly monitor the temperature and pressure of the coolant.

To check the latter, strain gauges with a Bourdon tube are usually used. To measure pressures of small magnitude, their varieties can be used - diaphragm instruments.

Figure 1 - Bourdon tube strain gauge

In systems where automatic control and regulation of pressure is provided, various types of sensors are additionally used (for example, electrocontact).

• at the inlet and outlet of the heating source;
• before and after the pump, filters, mud collectors, pressure regulators (if any);
• at the outlet of the main line from the CHP or boiler house and at its input into the building (with a centralized scheme).

Figure 2 - Section of the heating circuit with installed pressure gauges

How to trim heating

How to refuse heating in an apartment building?

Documentation

We will only partially touch on the documentary part. The problem is very painful; the permission to disconnect from the DH is given by organizations extremely reluctantly, and often they have to be knocked out through the courts. It is quite possible that in your case it will be much more useful not to have a technical article, but to consult a lawyer well-versed in the Housing Code.

The main steps are as follows:

1. We clarify whether there is a technical possibility to disable it. It is at this stage that most of the friction lies ahead: neither housing and communal services nor heat suppliers like to lose payers.
2. Technical conditions are being prepared for an autonomous heating system. You need to calculate the approximate gas consumption (in case you will be heated by it) and show that you are able to provide a safe temperature regime in the apartment for the building structures.
3. The act of fire control is signed.
4. If you plan to install a boiler with a closed burner and exhaust of combustion products on the facade of the building, you will need a permit signed by the Sanitary and Epidemiological Supervision.
5. A licensed installer is hired to complete the project. You will need a complete package of documents - from instructions for the boiler to a copy of the installer's license.
6. After the completion of the installation, a representative of the gas service is invited to connect the boiler and start it for the first time.
7. The last stage: you put the boiler for permanent service and notify the gas supplier of the transition to individual heating.

The technical side

Refusal of heating in an apartment building is due to the fact that you need to dismantle all heating devices without disrupting the operation of the heating system. How it's done?

In houses with a bottom filling, it is worth considering two cases separately:

• If you live on the top floor, you get the consent of the downstairs neighbors and move the jumper between the paired risers to them in the apartment. Thus, you completely isolate yourself from the CO. Of course, you will have to pay for welding, and installation of the air vent, and redecorating the ceiling from your neighbors.
• On the middle floor, only heating devices are dismantled, moreover with welding and cutting off the connections. A jumper of the same diameter as the rest of the pipe is cut into the riser. Then the riser is carefully insulated along its entire length.

Heating check valve

In a complex heating system, there is a fairly large number of auxiliary elements, the task of which is to ensure reliability and uninterrupted operation. One of these elements is the heating system check valve. The check valve is installed so that there is no flow in the opposite direction. Its elements have a very high hydraulic resistance. In this regard, there are restrictions on the use of non-return valves in a natural circulation heating system. In such a system, the pressure is too low. At minimum pressure it is necessary to install gravity valves with butterfly valves, some of them can operate at a pressure of 0.001 bar. The main part of the check valve is the spring, which is used in almost all models. It is the spring that closes the shutter when the normal parameters change. This is the principle of the check valve.

It is necessary to take into account the operating parameters in a particular heating system. In this connection, select the valve of the heating system, which has the necessary spring elasticity. The valves used in heating systems are usually made of the following materials: steel; brass; stainless steel; gray cast iron. Check valves are divided into the following types: poppet; petal; ball; bivalve. These types of valves are distinguished by a locking device.

Methods for organizing the supply and removal of coolant to heating radiators

There are three ways to connect radiators to the heating system:

• bottom;
• lateral;
• diagonal.

Bottom connection

In the literature, you can find other names for this method: saddle, sickle, "Leningrad". According to this scheme, both the supply of the coolant and the return are provided in the lower part of the radiators.It is advisable to use it if the heating pipes are located under the floor surface or under the baseboard.

Figure 1 - Bottom connection diagram

Figure 2 - Scheme of the movement of the coolant in the system with the bottom connection

Legend: 1 - Mayevsky crane 2 - Heating radiators 3 - Direction of heat flow 4 - Plug

It must be remembered that with a small number of sections or a small size of radiators, the bottom connection is the least efficient in terms of heat transfer (heat loss can be 15%) than other existing schemes.

Side connection

This is the most common way of connecting radiators to a heating system. When using such a scheme, the coolant is supplied to their upper part, while the return flow is organized from the same side from the bottom.

Figure 3 - Side connection diagram

Figure 4 - Scheme of the movement of the coolant in the system with side connection

It should be borne in mind that with an increase in the number of sections, the efficiency of such a connection decreases. To remedy the situation, it is recommended to use a fluid flow extension (injection lance).

Diagonal connection

This scheme is also called lateral cross, since the coolant is supplied to the radiator from above, while the return is organized from below, but from the opposite side. It is advisable to provide such a connection when using radiators with a large number of sections (14 or more).

Figure 5 - Diagonal connection diagram

Figure 6 - Scheme of the movement of the coolant in the system with a diagonal connection

You need to know that when you change the location of the supply and return, the heat transfer efficiency is halved.

The choice of one or another option for connecting radiators will largely depend on the envisaged pipe routing scheme (the way of organizing the return flow) in the heating system.

Layout of the pipeline in a multi-storey building

As a rule, in multi-storey buildings, a one-pipe wiring diagram with an upper or lower filling is used. The location of the straight and return pipe can vary depending on many factors, including even the region where the building is located. For example, a heating scheme in a five-story building will be structurally different from heating in a three-story building.

When designing a heating system, all these factors are taken into account, and the most successful scheme is created that allows you to bring all the parameters to the maximum. The project may involve various options for filling the coolant: from bottom to top or vice versa. In individual houses, universal risers are installed, which provide alternating movement of the coolant.

Heating pipe temperature table

The heating temperature, including the return pipes, directly depends on the indicators of street thermometers. The colder the air outside and the higher the wind speed, the greater the cost of heat.

A regulatory table has been developed that reflects the temperatures at the inlet, supply and outlet of the heat carrier in the heating system. The indicators presented in the table provide comfortable conditions for a person in a living room:

Pace. external, ° С	+8	+5	+1	-1	-2	-5	-10	-15	-20	-25	-30	-35
Pace. at the entrance	42	47	53	55	56	58	62	69	76	83	90	97	104
Pace. radiators	40	44	50	51	52	54	57	64	70	76	82	88	94
Pace. return lines	34	37	41	42	43	44	46	50	54	58	62	67	69

Important! the difference between the flow and return temperatures depends on the direction of flow of the heating medium. If the wiring is from above, the drops are no more than 20 ° С, if from below - 30 ° С

Return in the heating system, its purpose

The return in the heating system is a coolant that has passed through all the heating radiators, has lost its primary temperature and is already cold supplied to the boiler for the next heating. The coolant can move both in a two-pipe and in an improved one-pipe heating system.

A single-pipe heating system implies a sequence of connections for heating radiators.That is, the supply pipe is brought to the first radiator, from which the next pipe goes to the second radiator, and so on.

If the one-pipe heating system is improved, then its design will be something like this: there is one pipe along the perimeter of the entire room, into which you can insert the supply and return pipes of each radiator. In this case, for each battery there is the possibility of installing a control valve, with which you can very successfully regulate the air temperature in a given room.

The big advantage of such a heating system is the minimum number of pipes in it. And the minus is the temperature difference between the first radiator from the boiler and the last. This problem can be eliminated with the help of a circulation pump, which will drive all the water through the system and heating much faster, and thus the coolant will not have time to reduce the temperature.

A two-pipe heating system is a wiring of two pipes. One pipe is the supply of the hot coolant, the second pipe is the return flow in the heating system, through which the already cooled water from the radiators enters the boiler. Such a system allows almost parallel connection of all radiators, which makes it possible to flexibly configure each radiator separately, without affecting the operation of the others.

The consequences of a cold return

Return heating circuit

Sometimes, with an incorrectly designed project, the return flow in the heating system is cold. As practice shows, the fact that the room does not receive enough heat with a cold return is still half of the trouble. The fact is that at different supply and return temperatures, condensate can fall out on the walls of the boiler, which, when interacting with carbon dioxide released during fuel combustion, forms acid. She then can disable the boiler much ahead of time.

To avoid this, it is necessary to carefully consider the design of the heating system; special attention must be paid to such a nuance as the return temperature in the heating system. Or include additional devices in the system, for example, a circulation pump or a boiler, which will compensate for the loss of warm water

Radiator connection options

Now we can say with more than confidence that when designing a heating system, the supply and return must be ideally thought out and configured. With an incorrect design of the heating system, more than 50% of the heat can be lost.

There are three options for inserting a radiator into the heating system:

1. Diagonal.
2. Side.
3. Lower.

The diagonal system gives the highest efficiency factor and is therefore more practical and efficient.

The diagram shows a diagonal inset

How to regulate the temperature in the heating system?

In order to regulate the temperature of the radiator and reduce the difference between the flow and return temperatures, a heating system temperature controller can be used.

When installing this device, do not forget about the jumper, which must be located in front of the heater. In the absence of it, you will regulate the temperature of the batteries not only in your room, but also throughout the riser. It is unlikely that the neighbors will be delighted with such actions.

The simplest and cheapest version of the regulator is the installation of three valves: on the supply, on the return and on the jumper. If you close the valves on the radiator, the jumper must be open.

There is a huge abundance of different thermostats that can be used in apartment buildings and private homes. Among the wide variety, each consumer can choose a regulator for himself, which will suit him in terms of physical parameters and, of course, cost.

Types of radiators for heating apartment buildings

In multi-storey buildings, there is no single rule that allows you to use a specific type of radiator, so the choice is not particularly limited. The heating scheme of a multi-storey building is quite versatile and has a good balance between temperature and pressure.

The main models of radiators used in apartments include the following devices:

1. Cast iron batteries
   ... They are often used even in the most modern buildings. They are cheap and very easy to install: as a rule, apartment owners install this type of radiator on their own.
2. Steel heaters
   ... This option is a logical continuation of the development of new heating devices. Being more modern, steel heating panels show good aesthetic qualities, are quite reliable and practical. They are very well combined with the regulating elements of the heating system. Experts agree that it is steel batteries that can be called optimal when used in apartments.
3. Aluminum and bimetallic batteries
   ... Products made of aluminum are highly valued by owners of private houses and apartments. Aluminum batteries have the best performance when compared with previous versions: excellent external data, light weight and compactness are perfectly combined with high performance. The only drawback of these devices, which often scares off buyers, is the high cost. Nevertheless, experts do not recommend saving on heating and believe that such an investment will pay off pretty quickly.

Conclusion

The correct choice of batteries for a centralized heating system depends on the performance indicators that are inherent in the coolant in the area. Knowing the cooling rate of the coolant and the themes of its movement, it is possible to calculate the required number of radiator sections, its dimensions and material. Do not forget that when replacing heating devices, it is necessary to ensure compliance with all the rules, since their violation can lead to defects in the system, and then the heating in the wall of a panel house will not perform its functions (read: "Heating pipes in the wall ").

Centralized heating systems demonstrate good qualities, but they need to be constantly maintained in working order, and for this you need to monitor many indicators, including thermal insulation, wear of equipment and regular replacement of used elements.

How is the heating of a residential building arranged? The increase in tariffs prompts the transition to autonomous heating of the apartment; but the rejection of central heating in an apartment building, in addition to the mass of bureaucratic obstacles, also means a number of technical problems. To understand the ways to solve them, you need to imagine the layout of the coolant.