Does the ouzo trip when there is a short circuit? Protecting your home from fire and short circuit. The main problems of an unsecured network

The impact of electricity has a detrimental effect not only on human life and health, but also on the entire number of consumers who, without proper protection, fail. Differential protection devices have become widespread. Which is better: ouzo or differential automatic? To answer this question, it is necessary to study them in detail, and then draw conclusions.

Residual current devices

When laying electrical wiring or upgrading it, circuit breakers are not enough. The main criterion is electrical safety, because electricity not only has useful properties, but can also lead to huge problems (financial difficulties, threats to health and life).

To protect electrical wiring, devices and devices, specialized devices are used, which are called differential current devices. They protect not only from current leakage and from exceeding the electrical parameters of the network, but also from short circuits. This is a necessary measure, because it is impossible to control electricity while, for example, at work. This often leads to equipment failure, accidental fires and fires.

Nowadays, differential automatic devices and RCDs have become widespread. And many people are very concerned about ouzo or difavtomatic - what to choose?

Troubles when using home wiring

Before you begin choosing a differential protection model, you need to find out from what adverse factors the electrical network should be protected.

The main problems of an unsecured network:

Danger at home- electric shock to a person. For example, when you touch a pump or microwave, you feel the unpleasant effect of current on the human body. This is where the danger lies, because today there will be a weak blow, and after a while the phase will give a breakdown in the body of the product.

According to electrical safety regulations, a voltage of 220V and a current of 1.5mA are safe for humans. At currents up to 7 mA, convulsive phenomena are felt, and at 10 mA a person is no longer able to tear his hand away from the current-carrying part.

But these values in real life differ significantly. It all depends on the resistance of the person’s body and the method of touch. Body resistance depends on many factors, here are some of them: air humidity, moisture on the floor, shoes, clothing, genetic characteristics, nutrition and even mood.

Criteria for choosing differential protection

In order to clarify the next problem of choice (difavtomatic or ouzo - which is better?), it is necessary first of all understand their operating principle, scope of application, design features, occupied space, cost, difficulty of repair and connection, troubleshooting, ease of installation.

Design and installation features

For home use, single-phase ouzos are usually used and have a bipolar design. They must be used together with a circuit breaker, because the ouzo protects the electrical network or circuit section from leakage currents, and the circuit breaker protects from overloads and short circuits. This design occupies 3 modules in the panel.

Ordinary single-phase automatic circuit breaker made in 2-module, but there are models that are produced in a single-module design. If there are several difavtomats or several ouzos, then the space savings will be significant.

It is not difficult to install an ouzo or difavtomat - convenient clamps allow you to do this without problems, but there are some nuances here too.

For comparison, diagram 1 shows the switching of a pair of ouzo with an automatic machine and a difavtomat. Therefore, connecting the difavtomat is much simpler.

Scheme 1 - Scheme for comparing the switching of an ouzo+automatic machine and a difavtomatic machine

Diagnostics and maintainability of circuits

Each of the differential protection devices under consideration is designed for circuit break if triggered. To find out the reason why the operation occurred, it is necessary to carry out some diagnostics.

When a pair is installed (automatic and circuit breaker), the problem that has arisen can be immediately identified. When the ouzo was triggered, a current leak occurred on some line. If the circuit breaker has tripped, then there is an overload or short circuit in the electrical network.

But if the automatic transmission is installed, identifying the cause becomes more difficult. Some expensive models are equipped with a special indication that indicates leakage or overload.

Default protection devices may also fail. For example, with frequent triggering for no reason or with a clearly overloaded line. In this case, the thermal protection circuit is most likely faulty (malfunction of the bimetallic plate). In the case of a pair of RCD and AV, as a rule, 1 element fails, which can be replaced, which is cheaper than purchasing a breaker.

Operating principle of RCD and difavtomat

An RCD is used to identify and protect against leakage currents. The principle of operation is based on comparing the magnitudes of currents (incoming and outgoing).

Figure 1 - RCD (Residual current device or differential switch)

RCD device:

Toroidal transformer with 2 primary windings and one control winding.
Electromechanical relay (key).

The control winding is connected to the switch, and during normal operation of the device, the currents on the 2 primary coils create magnetic fluxes. Moreover, these coils are wound in opposite directions. When added together, these magnetic fluxes give a resulting magnetic flux in the core equal to zero. However, when a leakage current appears, this rule is violated, and a magnetic flux is formed on the control coil due to a difference in magnetic fluxes other than zero. This magnetic flux causes the switch to operate and the circuit opens. The response time of the RCD (differential switch) is in the range from 0.2 to 0.3 seconds.

Particularly widespread 30 mA devices, and in rooms with high humidity - 10 mA.

A difavtomat or automatic differential current switch (RCCB) combines an RCD and an AV (automatic circuit breaker).

Figure 2 - Difavtomat

Absolutely all RCBOs are superior to RCDs in response speed (0.04 seconds) and allow you to quickly turn off power to sections of the circuit during voltage surges over 250V.

Price

Solving this issue is quite simple. The cost of a pair of RCD and AV is lower than the cost of the automatic device itself. After all, if any element of this pair fails, it is necessary to replace the AV or RCD (cheaper than changing the automatic circuit breaker). It is advisable to immediately purchase high-quality devices, because the stingy pays twice. And when purchasing a high-quality differential protection device, fewer problems arise. The best brands are Schneider Electric, General Electric and ABB.

An example showing how to select a particular device.

A powerful device (15A and 1.5 kW) was purchased, to which a separate power supply line must be connected. For this case, you will need a 16A AV and an RCD (30mA). It is necessary to add up the costs of the devices and compare the resulting cost with the price of the RCBO. If it is necessary to install protection on 8 lines, each of which consists of 4 groups for a pair of RCD and CB: 6 AV * (cost of one CB) + 3 RCD * (cost of 1 RCD).

Nothing can be done for automatic machines, since 8 of them are needed (1 RCBO per 1 line). We calculate the amounts and find that installing RCBOs is much more expensive.

Main advantages and disadvantages

Having clarified the differences between the two differential protection devices, a number of advantages and disadvantages can be formed.

However, it is quite difficult to find out, because you need to be guided by the specific situation and the parameters of the electrical wiring lines, as well as the devices connected to this network.

The main disadvantages of the difavtomat:

Diagnostic problem: it is difficult to diagnose the reason for the device’s operation, although there are expensive models that provide this function.
Financial side: it costs more than an RCD and if it fails, you need to buy a new one.

Disadvantages of RCD:

High response time relative to RCBOs.
Takes up more space during installation.
Must be used together with AB.

Advantages of the automatic machine:

High response speed.
Ease of installation.
Takes up less space in the box.

Advantages of RCD with AV:

Relatively low price.
Easy diagnostics.
Better maintainability.

If we take into account that the reliability of RCD+AV and RCBO is the same (low-cost options are not considered), then the main criterion for choosing a device is, first of all, its cost. After all, everything depends on financial capabilities.

Key aspects to consider when choosing:

Installation and connection diagrams: not particularly difficult.
Diagnostics: when connecting the RCBO, finding the cause is not a problem, because there is a light indication.
There is no need to save on a spacious shield; perhaps someday you will need to draw another line, which also needs to be protected.

Thus, when choosing a specific differential protection device, you need to think about everything, draw up a rough plan for dividing the power supply lines of a residential premises, decide on consumers, calculate the total possible power of consumers for each line and, based on the financial situation, make the final choice. The main difference and main criterion is the price, but you should not save, because this is your safety, as well as minimizing financial problems.

RCD(Residual Disconnection Device) is a switching device designed to protect an electrical circuit from leakage currents, that is, currents flowing along undesirable, under normal operating conditions, conductive paths, which in turn provides protection from fires (electrical wiring fires) and from electric shock to humans. electric shock

The definition of “switching” means that this device can turn on and off electrical circuits, in other words, switch them.

RCD also has other names, for example: differential switch, differential current switch, (abbreviated as differential current switch), etc.

Design and operating principle of RCD

And so, for clarity, let’s present the simplest diagram of connecting a light bulb through an RCD:

The diagram shows that during normal operation of the RCD, when its moving contacts are closed, a current I 1 of value, for example, 5 Amperes from the phase wire passes through the magnetic circuit of the RCD, then through the light bulb, and returns to the network via the neutral conductor, also through magnetic circuit of the RCD, and the value of the current I 2 is equal to the value of the current I 1 and is 5 Amperes.

Connection diagram of the RCD in the electrical network(when the neutral working and neutral protective conductors are separated):

IMPORTANT! In the coverage area of the RCD, you cannot combine the neutral protective (grounding wire) and the neutral working conductors! In other words, it is impossible in the circuit, after the installed RCD, to connect the working zero (blue wire in the diagram) and the ground wire (green wire in the diagram).

Errors in connection diagrams due to which the RCD trips.

As mentioned above, the RCD is triggered by leakage currents, i.e. if the RCD has tripped, this means that a person has come under voltage or for some reason the insulation of the electrical wiring or electrical equipment has been damaged.

But what if the RCD trips spontaneously and there is no damage anywhere, and the connected electrical equipment is working properly? Perhaps the whole point is one of the following errors in the network diagram of the protected RCD.

One of the most common mistakes is combining the neutral protective and neutral working conductors in the coverage area of the RCD:

In this case, the amount of current leaving the network through the RCD along the phase wire will be greater than the amount of current returning to the network through the neutral conductor because part of the current will flow past the RCD along the grounding conductor, which will cause the RCD to trip.

Also, there are often cases of using a grounding conductor or a third-party conductive grounded part (for example, building fittings, a heating system, a water pipe) as a neutral working conductor. This connection usually occurs when the neutral working conductor is damaged:

Both of these cases lead to the RCD tripping, because The current leaving the network through the phase wire does not return through the RCD back to the network.

How to choose an RCD? Types and characteristics of RCD.

To choose the right RCD and eliminate the possibility of error, use ours.

The RCD is selected according to its main characteristics. These include:

Rated current— the maximum current at which the RCD can operate for a long time without losing its functionality;
Differential current— the minimum leakage current at which the RCD will disconnect the electrical circuit;
Rated voltage- voltage at which the RCD is able to operate for a long time without losing its functionality
Current type— constant (denoted by “-“) or variable (denoted by “~”);
Conditional short circuit current- current that the RCD can withstand for a short time until the protective equipment (fuse or circuit breaker) trips.

RCD selection is based on the following criteria:

— By rated voltage and network type: The rated voltage of the RCD must be greater than or equal to the rated voltage of the circuit it protects:

Unom. RCD⩾ Unom. networks

At single-phase network required two-pole RCD, at three-phase network — four-pole.

— By rated current: The rated current of the RCD must be greater than or equal to the rated current of the circuit it protects, i.e. the current for which this electrical network is designed:

Inom. RCD⩾ Icalc. networks

The network current can be calculated using ours, or it can be determined independently using the formula

Inetworks= Pnetworks*K p, Ampere

Where: Pnetworks— network power, in kilowatts; K p— conversion factor equal to: 1,52 -for 380 Volt network or 4,55 - for a 220 Volt network:

After calculating the mains current, we accept the nearest higher standard value of the rated current of the RCD: 4A, 5A, 6A, 8A, 10A, 13A, 16A, 20A, 25A, 32A, 40A, 50A, 63A, etc., and it is recommended to accept the RCD with rated current one step higher than calculated, for example, if as a result of the calculation the network current was 22 Amperes, then the nearest standard value of the rated current of the RCD will be 25 Amperes, however, you should select an RCD with a rated current one step higher, i.e. 32 Amps.

The power of the network is determined by summing the powers of all electrical receivers connected to the network protected by the calculated RCD:

P network =(P 1 + P 2 ...+ P n)*K s, kW

Where: P1, P2, Pn— power of individual electrical receivers in kilowatts; K s— demand coefficient (K c = from 0.65 to 0.8) if only 1 power receiver or a group of power receivers that are connected to the network at the same time is connected to the network K c = 1.

As the network power, you can also take the maximum power allowed for use, for example, from technical conditions, a project or a power supply contract, if any.

Because The RCD does not have protection against short circuit currents; it must be protected by a fuse or circuit breaker installed in the circuit. The rated current of the RCD can also be selected based on the rated current of the fuse or circuit breaker, and it is recommended that the rated current of the RCD be one step higher than the rated current of the protection device.

For example: You determined the calculated network current which was 22A (Ampere), from the line of standard ratings: 4A, 5A, 6A, 8A, 10A, 13A, 16A, 25A, 32A, 40A, 50A, 63A, you selected the closest value of the rated current of the automatic switch - 25A, then it is recommended that you take an RCD with a rated current of 32A.

— By differential current:

Differential current is one of the main characteristics of the RCD, which shows at what value of leakage current the RCD will turn off the circuit.

In accordance with paragraph 7.1.83. PUE: The total leakage current of the network, taking into account the connected stationary and portable electrical receivers in normal operation, should not exceed 1/3 of the rated current of the RCD. In the absence of data, the leakage current of electrical receivers should be taken at the rate of 0.4 mA per 1 A of load current, and the network leakage current at the rate of 10 μA per 1 m of phase conductor length. Those. The differential network current can be calculated using the following formula:

Δ I network =((0.4*I network)+(0.01*L wire))*3, milliampere

Where: Inetworks— network current (calculated using the formula above), in Amperes; Lwires— total length of the protected electrical network wiring in meters.

Having calculated ΔI network we accept the nearest higher standard value of the residual current of the RCD Δ I RCD:

Δ I RCD ⩾ ΔI network

The standard values of the residual current of the RCD are: 6, 10, 30, 100, 300, 500mA

Differential currents: 100, 300 and 500 mA are used for protection against fires, and currents: 6, 10, 30 mA are used to protect against electric shock. In this case, currents of 6 and 10 mA are used, as a rule, to protect individual consumers and, and a differential current of 30 mA is suitable for general protection of the electrical network.

If an RCD is needed to protect against electric shock, and according to the calculation, the leakage current is more than 30 mA, it is necessary to provide for the installation of several RCDs on different groups of lines, for example, one RCD to protect sockets in rooms, and a second to protect sockets in the kitchen, thereby reducing the most power passing through each RCD and, as a result, reducing the network leakage current, i.e. in this case, the calculation will need to be made for two or more RCDs that will be installed on different lines.

— By type of RCD:

There are two types of RCDs: electromechanical And electronic. We discussed the principle of operation of an electromechanical RCD above; its main working element is a differential transformer (magnetic core with a winding) that compares the magnitude of the current going into the network and the current returning from the network, and in an electronic device this function is performed by an electronic board that requires voltage to operate.

How the RCD works:

All RCDs belong to the category of electronic protective equipment. However, in terms of its functionality, the residual current device differs significantly from standard circuit breakers. What is their difference, and how does an RCD work in comparison with an automatic machine?

Everyone knows that over time, wire insulation ages. Damage may occur, and the contacts connecting live parts gradually weaken. These factors ultimately lead to current leakage, which causes sparking and further fire. Often, people may accidentally touch such emergency phase wires that are under voltage. In this situation, electric shock poses a serious danger.

Purpose of RCD

Residual current devices must respond to even minor short-term current leaks. This is their main difference from circuit breakers, which operate only during overloads and short circuits. Automatic machines have a very high time-current response characteristic, while an RCD operates almost instantly, in the presence of even the most minimal leakage current.

The main purpose of the RCD is to protect people from possible electric shocks, as well as to prevent dangerous current leaks.

Operating principles of RCD

From a technical point of view, any RCD is a high-speed switch. The operating principles of the residual current device are based on the response of the current sensor to the changing current flowing in the conductors. It is through these conductors that current is supplied to the electrical installation, which is protected by the RCD. A differential transformer is wound onto the core, which is a current sensor.

To determine the response threshold of an RCD having a certain current value, a highly sensitive magnetoelectric relay is used. The reliability of relay structures is considered quite high. In addition to relay ones, electronic device designs have now begun to appear. Here the threshold element is determined by a special electronic circuit.

However, conventional relay devices seem to be more reliable. The actuator is activated using a relay; as a result, the electrical circuit is broken. This mechanism consists of two main elements: a contact group designed for maximum current and a spring drive that breaks the circuit in the event of an emergency.

To check the serviceability of the device, there is a special circuit inside it that artificially creates a current leak. This triggers the device and makes it possible to periodically check its serviceability without calling specialists to carry out electrical measurements.

The direct operation of the RCD is carried out according to the following scheme. A situation should be considered where the power supply system is operating normally and there are no leakage currents. The operating current passes through the transformer and induces magnetic fluxes directed towards each other and equal in magnitude. When they interact, the current in the secondary winding of the transformer has a zero value, and the threshold element does not operate. When a current leak occurs, an imbalance of currents in the primary winding occurs. Because of this, a current appears in the secondary winding. Thanks to this current, the threshold element is triggered, and the actuator is activated and de-energizes the controlled circuit.

From a technical point of view, the residual current device consists of a fire-resistant plastic housing. On its back there are special locks for installation on an electrical panel. In addition to the elements already discussed, an arc suppression chamber is installed inside the housing, which neutralizes the electric discharge arc. Clamps are used to connect the wires.

RCD operation parameters

To correctly select the device trigger setting, you should remember the danger of alternating current to humans. Under its influence, cardiac fibrillation occurs when contractions are equal to the frequency of the current, that is, 50 times per second. This condition causes a current starting from 100 milliamps.

Therefore, the settings at which the RCD is triggered are selected with a margin of 10 and 30 milliamps. The lowest values are used in high-risk areas, such as bathrooms. The highest settings are 300 mA. RCDs with such settings are used in buildings, protecting them from fires due to damaged circuits.

When choosing an RCD, the rated current, required sensitivity and number of poles are taken into account, in accordance with the phases of the supply network. It is necessary to check the degree of thermal stability of the device, as well as the ability to turn it on and off, based on the calculated network parameters.

The rated current value for the RCD must be higher than that of the machine. A lower current rating of the machine will protect the RCD from damage in the event of a short circuit in the circuit.

How to connect an RCD

All terminals on the RCD body are marked with the corresponding letters. Terminal N is for the neutral wire, and L is for the phase wire. Therefore, they must be connected to their own terminals.

Also, it is necessary to take into account the position of the entrance and exit and under no circumstances change their places. The entrance is located at the top of the device. The power wires running through the input machine are connected to it. The output is located at the bottom of the RCD and the load is connected to it. If you confuse the position of the input and output, then false triggering of the residual current device or its complete failure may occur.

Installation of RCDs is carried out together with conventional circuit breakers. Thus, devices installed together provide protection not only from short circuits and overloads, but also from leakage currents. At the same time, the RCD itself, which is connected behind the input machine, is protected.

Connecting a residual current device in an apartment or private house has its own characteristics. For apartments where a single-phase network is used, the RCD connection diagram is assembled as follows, following a certain sequence: input machine => electricity meter => RCD itself with a leakage current of 30 mA => the entire electrical network. For consumers with high power, it is recommended to use their own cable lines with the connection of separate residual current devices.

In large private houses, the connection diagram for protective devices differs from apartments due to its specifics. Here, all devices are connected as follows: input circuit breaker => electricity meter => input RCD with selective action (100-300 mA) => circuit breakers for individual consumers => RCD for 10-30 mA for individual groups of consumers.

RCD errors when connecting

Correct connection of protective devices is the key to reliable operation of the entire electrical network.

RCD - residual current device. Many have probably heard, and someone may know what this device is, what it is for and how it works. Without delving too much into the jungle of physics, we will briefly try to understand the structure and operating principles of this very thing in simple human language.

So, as the name itself suggests, This device is designed to protect against electric shock. The operating principle of the device is based on comparing the currents along the conductors at the input and output of the device. The currents must be equal. If there is a slight difference, the device “sees” it and immediately disconnects the load from the network. The response time, according to standards, should be no more than 15-25 ms.

For example, if an insulation breakdown occurs on the body, and it doesn’t matter whether it is a phase wire or a neutral wire, in any case, when a person touches the body of the device, it will happen through the person’s body, to which the RCD will immediately respond and turn off the damaged device, thereby saving the person life. Here is, perhaps, the simplest and most understandable example, for a person far from physics.

Now, in fact, we will begin to review the reasons due to which, in practice, the RCD is triggered.

As we found out earlier, The RCD is triggered when current leakage occurs. Cracks in the insulation of worn-out wires in older buildings can cause this type of leakage. In this case, the activation of the protection prevents the occurrence of a fire.

What to do in this case? There is only one answer - look for possible places of current leakage. You can, of course, get by with simpler methods, for example, simply eliminating the RCD from the circuit, but no one knows what this will lead to.

The wiring can last for decades, but it can also lead to disaster. And electricity, as you know, does not like jokes and does not forgive negligence.

In addition to wear and tear on the wires, the tripping of an RCD often causes wear and tear, and therefore breakdown of insulation in household appliances. For example, sometimes old refrigerators, washing machines, etc. can cause the RCD to trip.

Sometimes, in 50% of cases, manipulation of the plug and socket helps to get rid of the RCD triggering, that is, simply turn the plug over in the socket.

Video on the topic. The RCD can also be switched off if it is connected incorrectly. The reasons for the RCD tripping are installation errors. The main mistakes are discussed in this video.

Residual current device (RCD) and differential protection (Difavtomat)

INIn this article, the author will try to explain as simply as possible the purpose, design features, technical characteristics of RCDs (electromechanical and electronic) and differential protections, differential circuit breakers, or as commonly abbreviated as differential circuit breakers, as well as their differences, examples of connection diagrams, etc..

Let's start with the Rules, or rather, excerpts from the Rules and pay attention to the highlighted text (must, allowed, mandatory, required, recommended, etc., so that you can decide for yourself where it is mandatory to install an RCD or a Difavtomat, and where, at your discretion, to install or not).

Go to page PUE 7 excerpts from:

In general, the conclusion from the Rules is this: RCDs are not a panacea for all problems with electricity, but work in conjunction with other protective devices and can be installed in accordance with the Rules, where it is mandatory, and where it is not necessary, but recommended.

Purpose of RCD and differential protection:

A residual current device (RCD) or a differential circuit breaker is used to protect people from electric shock in industry, agriculture, everyday life, etc. Moreover, they cannot be considered as an alternative to other safety measures; moreover, the GOST R-30331.3 standard classifies them as auxiliary devices and additional methods of protection from direct touch . For these purposes, as well as for protection against indirect contact in the Russian Federation, RCD-D with diff. shutdown current is about 30ms. Devices with large diff. current shutdowns are used to protect electrical equipment from the consequences of leakage currents (fires, equipment failure).

Direct touch:
Direct touch refers to human contact with a part of the electrical wiring that is energized during operation. In other words, a person touching open wires, contacts, terminals through which electric current flows in normal (not emergency) modes is a direct touch.

Indirect touch:

Indirect touch is inherently more dangerous than direct touch. If a direct touch is more likely an accident caused by an oversight, then an indirect touch occurs in an emergency situation and the person does not know in advance that this or that structure is energized.

Table of damage current values and its consequences for human exposure:

How the RCD works:

Inside the RCD there is a special transformer (see Fig. 1), in which each of the conductors (L-phase, N-zero) creates an electromagnetic field. During normal operation, they cancel each other. When a current leak occurs, an imbalance of the electromagnetic field occurs in the coil, as a result, the rod pushes the lever to turn off. Such a device is triggered to switch off from current leakage, but is not intended to protect against short circuits and network overloads, i.e. the residual current device itself reacts only to differential currents and does not operate with short-circuit currents (phase-zero) and overload currents, so it is necessary to install an additional circuit breaker. In Fig. Figure 1 shows a purely schematic diagram of the operation of an RCD; the device itself contains many more elements - filters for protection against interference and false alarms and some other electronic components, but the described principle of operation is basic for residual current devices.

Rice. 2 Fig. 3

The operating principle of an RCD is based on measuring the current difference in conductors passing through a differential current transformer. The RCD measures the vector sum of currents flowing through the controlled conductors (two for a single-phase RCD, three or more for a three-phase version). In normal operating mode, the vector sum of the currents flowing through the measuring transformer is 0 (the current “flowing” through one conductors is equal to the current “flowing out” through the others, see Fig. 2), and the device does not operate. When a leakage current appears (a person touches the phase conductor, or a decrease in the insulation resistance of the cable line), the vector sum of the currents flowing through the RCD will not be equal to 0, since a leakage current appears that flows only through the phase conductor (see Fig. 3), in a voltage proportional to the leakage current will be induced in the secondary winding of the transformer, and if a certain threshold is exceeded, the device will operate and the protected circuit will be disconnected.

RCDs are single-phase and three-phase. In addition, there are now two different types of RCDs on sale, differing both in price and reliability - electromechanical and electronic RCDs, see Fig. 4:

Rice. 4 RCD diagrams and designations

In terms of design, it is important to note that:

Single-phase RCDs, which are most often used in everyday life, usually have a two-pole design, i.e. when installed in an electrical panel on a DIN rail, two modules are occupied. If we do not consider replacing the input circuit breaker + RCD with a differential circuit breaker, then usually a single-pole circuit breaker is installed in series with the RCD. In the general case, a combination of RCD + circuit breaker when installed on a DIN rail will occupy three modules, and a differential circuit breaker will occupy two modules (which is important when installing in panels to save space for circuit breakers). It turns out two in one: RCD + Circuit breaker = Differential circuit breaker.

How to choose the right RCD, electronic or electromagnetic, first of all, look at the technical characteristics of the device, the manufacturer’s workmanship, in addition, residual current devices are of type A and AC, which is further described in detail in the following articles:

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Differential circuit breaker:

Differential circuit breaker (differential current protection and general protection), designed to protect the circuit from current leakage (similar to the operation of an RCD), but the advantage of differential. machine is that it has a built-in circuit breaker, which performs the function of protecting the circuit from short circuits and overloads.

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