ITCO20120036A1 - PROGRAMMABLE MULTIPLE ELECTRIC SOCKET. - Google Patents

Description

DESCRIPTION of the patent application for industrial invention having

TITLE: «Multiple programmable electrical socket».

TEXT OF THE DESCRIPTION

1. FIELD OF TECHNIQUE

This industrial invention refers to the field of multiple electrical sockets operating in master slave mode.

In multiple electrical sockets operating in master-slave mode, one socket called master controls the connection to the electrical network of the other sockets called slave of the first. More precisely, the absorption, by the user connected to the socket acting as master, of a current intensity above a certain value set as a threshold, determines the connection to the mains of all the sockets operating in mode slave of the first and the absorption of a current intensity below a certain value set as a threshold, by the user connected to the master socket, determines the disconnection from the electrical network of all the slave sockets, so that the sockets that act as slave they are connected to the mains if and only if the device connected to the socket acting as master absorbs a current intensity above a certain value set as a threshold.

Using multiple electrical sockets operated in master-slave mode it is not necessary for the user to turn on all equipment operating in slave mode, as this is done automatically by the control system when the user turns on the equipment operating in master mode. In this way, greater ease of use is achieved, which also translates into energy savings compared to the use of multiple sockets that do not provide for any automatic control of the connection of the sockets to the power source since, often, the operation the shutdown of all the equipment is not performed by the user, while, in the multiple sockets operated in master-slave mode, the shutdown of the slave devices is carried out automatically by the control device, when the user turns off the equipment that acts as a master or when it switches off automatically.

2. TECHNICAL PROBLEMS

One of the technical problems of multiple sockets operating in master-slave mode derives from the impossibility of connecting more than one set of equipment operating in master-slave mode. For example: if it is necessary to connect two or more computers with the related peripherals, it is not possible to use a single multiple socket operating in master-slave mode but, it is necessary to use two or more, and note that all master-slave multiple socket-outlets they must then be connected to a multiple socket that does not provide for any automatic control of the connection of the sockets to the power source. There is therefore a proliferation of multiple sockets to be used, of electrical cables and of the space occupied.

A subdivision of the available sockets into several subgroups of sockets operating in master-slave mode operated a priori by the manufacturer, for example: a multiple socket equipped with six sockets divided into two completely independent subgroups of three sockets operating in master slave mode [each subgroup formed by a master and two slaves], would have a flexibility problem, since if three peripherals were to be connected to a computer instead of two, or three computers instead of two, the multiple socket would not be sufficient by itself for the connection of all users.

3. SOLUTIONS TO PROBLEMS

The solution found uses an electronic, logical and programmable system for the automatic control of the connection to the electricity source of the available sockets, in order to ensure maximum flexibility of use, allowing the creation of ad hoc, among the sockets of the invention, multiple grip combinations, each operating in master-skier mode entirely independently of the other grip combinations.

The solution found also allows the programming of the operation of sockets in a completely independent mode from the operation of the other sockets, even allowing the operation of all the sockets available as "normal" electrical sockets, thus behaving, if necessary, as a "normal" multiple electrical socket, that is, as a multiple socket without any automatic control of the connection of the sockets to the power source, thus increasing even more its flexibility of use, compared to multiple sockets operating in master-slave.

The solution found has another useful function that allows greater flexibility of use, and which consists in the possibility of programming the logic control system so that one or more sockets operate in slave mode of more than one master, meaning, by said operating mode that, the slave socket is disconnected from the mains, only if all the master sockets, to which the slave socket is associated, absorb a current intensity below a certain value set as a threshold and that the socket slave is connected to the mains when one or more master sockets, to which the slave socket is associated, absorb a current whose value is above the value set as threshold, it is sufficient that even a single master socket absorbs a current intensity whose value is above the threshold for the slave socket to be connected to the power source. This mode of operation is very useful if there are peripherals shared among several computers such as a printer, because the printer must only turn off if all the computers are turned off, while it must remain on even if only one computer is turned on.

The programming of the operation of the multiple electrical socket found is very simple because it is carried out simply by inserting the user plugs into the electrical sockets of the invention.

To program the operation of the sockets in master-slave mode, it is necessary to insert, first, the plug of the user that you want to operate as master, in any of the free sockets and, within a certain time interval [said interval of 'insertion and typically consisting in one minute], all the plugs of the users that it is desired to operate as a slave of the selected master user, in any sequence of insertion, using any combination of sockets among those left free.

If you want to insert other groups of users that work in master-slave mode, and in a completely independent way from the other groups previously inserted, simply repeat the operation of inserting the plugs, connecting them to the sockets left free, and taking care to insert for first the plug of the user that you want to operate as the master of the new group of devices, and then, the plugs of the users who will act as the slave of the chosen master. All the operations for inserting the plugs of a group of users operating in master-slave mode must be completed before the insertion interval from the connection of the first plug, that of the user chosen as master, on the other hand, between the insertion of two plugs of users operating in master mode [belonging to two different groups of users operating in master-slave mode], the insertion interval must at least completely elapse. For example: a computer plug is inserted, then, within a minute, the monitor, amplifier, scanner and printer plug; after at least one minute from the insertion of the computer plug, you can insert the plug of a second computer, then, within a minute, the peripheral plugs of the second computer and so on, allowing at least a minute to pass between inserting the plug one computer and the other and plugging in all peripherals within one minute of plugging the last computer. In this way, turning the first computer on and off will turn on and off only the peripherals of the first computer, while turning the second computer on and off will turn on and off only the peripherals of the second computer.

The programming of the operation of sockets in which to insert the plugs of devices intended to function autonomously, not acting either as master or slave is the simplest of all, just inserting the plugs of said devices intended to function independently [such as a lamp], in any free socket, taking care not to connect other plugs before at least the entire insertion interval [typically one minute] has elapsed. In the programming of the operation, the sockets operating independently from the others will simply be considered as the master without any slave.

The programming of a selected user as a slave of more than one master, is carried out by programming its functioning as a slave for all groups of users operating in master-slave mode who have a master who is to be associated with the selected user as a slave of more than a master.

It will therefore be necessary to insert the plug of the selected user who will act as a slave for more than one master, after having inserted the plug of the first user who will act as master and before the insertion interval expires, thus programming its operation. as a slave to one master; subsequently, it will be necessary to simply repeat the programming operation, disconnecting and reinserting in the same socket, the plug of the user who will act as a slave to more than one master, after having inserted the plug of the user who will act as master and before the expiry of the 'insertion interval, for all groups of users who have a master who is to be associated with the selected slave of more than one master.

For example: you insert the plug of a computer, then that of the monitor, and then that of the printer, and you let at least a minute pass, then you insert the plug of another computer and then that of the monitor and, before that has elapsed one minute after inserting the plug of the second computer, the printer plug is unplugged and reinserted in the same socket. In this way the printer will be slave to both computers and will be turned off only if both computers are turned off or in stand-by.

4. ADVANTAGEOUS EFFECTS OF THE INVENTION

Thanks to this industrial invention it is possible to connect to a single multiple socket more than one group of user devices operating in master-slave mode, each group not having a number predetermined by the manufacturer but dependent on the user's needs, moreover, it is possible to connect devices that work in complete autonomy and even devices that disconnect from the mains only when all associated users are off or in stand-by [in the operating mode called slave of more than one master].

The advantage of the invention therefore consists above all in the flexibility of use. There is also a saving of multiple sockets and electric cables, therefore, an economic saving. Finally, there is the advantage of a reduction of the occupied space and an improvement of the order.

5. DESCRIPTION OF THE FIGURES

Figure 1 shows the solution found as it appears, from the outside, ie as a normal multiple electrical socket [1] with several sockets [2] and the cable [3] for connection to the network.

6. METHOD OF IMPLEMENTATION

Figure 2 represents the wiring diagram of one of the possible implementations of the multiple socket found, an implementation equipped with twelve electrical sockets [1] and a plug [2] for connection to the network. Twelve normally closed buttons [3], each associated with one of the twelve available sockets, open when a plug is inserted into the corresponding socket, remaining open as long as the plug is inserted in the socket. The binary digital signal corresponding to the state: plug inserted in the socket [logic one], or corresponding to the state: socket free [logic zero], is sent to the programmable logic system [5]. There are also twelve sensor-actuator devices [4], each connected to only one of the twelve sockets.

Figure 3 shows the wiring diagram of the actuator-sensor devices [4] shown in figure 2. From the examination of figures 2 and 3, it is possible to understand that the actuator-sensor devices [4] send the logic signal Cur to the programmable logic system [5] and from this they receive the logic signal Rei, moreover, each of said elements has connected a socket between the Pluga and Plugb terminals [see figure 3]. As shown, a relay RL with normally closed contacts was chosen as the actuator element and a coil L wound around the connection wire of the electrical socket, as a sensor element for the current absorbed by the device connected to the socket. Basically, the circuit shown in Figure 3 is divided into two parts, one for implementation and the other for sensory. As far as the sensory part is concerned, a voltage corresponding to a high logic level on the Cur terminal indicates that the current in the corresponding socket is higher than the established threshold level and that therefore the connected electrical device must be considered switched on, while a low logic level indicates that the current flowing into the socket is below the established threshold and the connected electronic device must be considered off or in stand-by. By adjusting the trimmer RI it is possible to adjust the aforementioned threshold, in fact, by acting on the trimmer RI the amplification ratio of the operational amplifier OA is varied. The diode D2 serves to straighten the signal coming from the coil L, while the filter consisting of the resistor R3 and the capacitor C1 serves to stabilize it. Resistor R4 is a discharge resistor which serves to restore the Cur signal to zero when the device connected to the socket is switched off. As regards the actuating part of the circuit, a high voltage on the Rei terminal saturates the transistor T and consequently excites the coil of the relay RL which opens the normally closed contact by disconnecting the socket from the mains. Diode DI serves to limit the overvoltages produced by the relay coil RL. As can be deduced from Figure 2, the Pluga and Plugb contacts shown in Figure 3 are connected in series to the corresponding electrical socket, so that a high logic signal on the Rei terminal switches off the device connected to the socket.

Figure 4 shows the block diagram of the programmable logic system [5] shown in figure 2. In the block diagram, for reasons of space, only the first and twelfth of the twelve sections are shown, one for each of the twelve sockets of which the illustrated implementation of the invention is provided. The CODEC blocks deal with the transformation of digital signals, while the CONTROL blocks are used to control the REG blocks which are P.I.P.O. registers. The Busln connects the inputs of the twelve REG registers, while the BusOut connects the outputs. The ControlBus is a control bus, formed by four bits, which serves to transmit information to the control logic [CONTROL blocks] of all twelve sections of the programmable logic control system of the invention.

Figure 5 shows the internal wiring diagram of the CODEC blocks shown in Figure 4. The wiring diagram is basically divided into three circuits: one that deals with the transformation of the digital signal Plg [1 plug inserted into socket 0 empty socket], one that is deals with the transformation of the digital signal Cur [1 device on 0 device off] and one that generates the Rei signal that drives the relay RL. These are essentially two monostable dual circuits and an enable S-R latch.

If a plug is inserted into the socket, the signal Plg [plug] passes from zero to one, thanks to the pull-up resistor RIO and, consequently, an impulse with a duration determined by τ, η is generated at the output Plgln [plug in] = C4 * R9 = 60 s, while, if a plug is removed from the socket, the signal Plg [plug] passes from one to zero and consequently an impulse of the duration determined by Tout = C5 is generated at the output PlgOut [plug out] * R11 = 60 s.

If the device connected to one of the sockets of the invention is switched on, it begins to absorb current, and consequently the signal Cur [current] assumes logic level one, and consequently the CVar [current variation] and COn [current on] outputs are generated a pulse of the duration determined by

T0n = C3 * R8 = l s. If the device connected to the socket is switched off, it ceases to absorb current, and consequently the Cur signal assumes the logic level zero and, consequently, an impulse with a duration determined by i0ff = C2 is generated at the CVar and COff [current off] outputs * R7 = 1 s. In summary, every time the operating status of the device connected to the socket changes, an impulse with a duration of approximately ls is generated on the CVar output terminal, while only when the device connected to the socket is switched on, an impulse with a duration of approximately ls on the output terminal COn, similarly, only when the device connected to the socket is switched off, a pulse with a duration of approximately ls is generated on the output terminal COff.

As can be seen from figure 4, the signals COff and COn are transmitted by the CODEC blocks through the ControlBus to all twelve sections of the control system, while the CVar signal is sent only to the CONTROL block of the same section. Figure 4 also shows that the Enb [enable] signal is an input signal for the CODEC, coming from the CONTROL of the same section and is not transmitted to the other sections.

From figure 5 we can see that the enabling signal Enb is the enabling signal [through gates AND5 and AND6] of an S-R type LATCH. If the Enb signal is high, the LATCH is enabled and, consequently, if the COn signal is high, the LATCH is set, the Rei signal is low and the contacts of the RL relay are closed and the device is switched on, while, if it is the COff signal to be high, the LATCH is Reset and the Rei signal is high and the RL relay contacts are open and the device is off.

Figure 6 shows the internal electrical diagram of the CONTROL blocks of the twelve sections of the circuit shown in Figure 4. It is essentially the control logic of the registers REG. We can see that the register control circuit is essentially divided into two parts: a part concerning the programming of the operation, essentially dealing with the writing of the register REG and which includes the LATCHCTRL, [which is an S-R type latch] and the AND7 gates. , AND8 and AND9 and, another part, which essentially deals with reading the register REG, which is constituted by the logic gates AND10 and AND11.

Let us now try to analyze the operation of the CONTROL block shown in figure 6. Initially the LATCHCTRL is reset.

By inserting an electric plug into a socket of the invention, the CODEC circuit of the corresponding section transmits a Plgln [plug in] signal which finds the AND7 gate open [since the AND9 gate is closed, the Slv [slave] signal is low]. in this way, the LATCHCTRL which closes gate AND8 and opens gate AND9, occupies the register REG for writing [see Figure 4] by means of signal W [write]. The LATCHCTRL setting indicates that a device that will function as master is connected to the corresponding section and for this reason a high signal is sent to the Slv [slave] bit of the ControlBus [for opening the END9 port], while the Busln signal becomes low since gate END8 has been closed [and this prevents a one from being written to the bit corresponding to the same section of the REG register, which would disconnect the master device].

On the other hand, by disconnecting the electrical plug from a socket, the CODEC circuit generates the PlgOut [plug out] signal which resets the LATCHCTRL and deletes the REG register through the CL [clear] signal, ensuring that the entire operating programming that saw the connected device as master to be erased.

Figure 7 shows the internal wiring diagram of the REG block. It is basically a Parallel Input Parallel Output register, made up of 12 S-R latches, with three state output and with erase pin [CL].

Fig. 8 shows in detail the connection of the control blocks [CONTROL] and of the registers [REG] to the Busln. We can better understand, by observing this diagram, the overall operation of the device. By inserting a plug [see figure 2] into socket [1], the corresponding normally closed button [3] opens, raising the signal Plg from 0 to 1 [see figure 5] through the pull-up resistor RIO . The monostable circuit constituted by gate AND3 generates an impulsive signal Plgln [plug in] with a duration Tin = C4 * R9 = 60 s. The signal Plgln [see figure 6] finds gate AND7 open and causes LATCHCTRL to be set to one, which closes gate AND8 bringing the signal Buslnl to zero and opens gate AND9, sending the enabling signal to register REG on writing W, moreover, the signal Slv [slave] transmitted through the ControlBus to all twelve sections of the implementation of the invention is brought to one, indicating that there is already a master and that consequently any other plugs inserted must become slave. Setting the LATCHCTRL to one, as in this case, indicates that the section acts as a master, while a reset to zero indicates that the section acts as a slave. Figure 8 shows the situation that occurs after inserting a plug into the socket of section 1. In the register REG of the first section of the invention, the first bit has not been brought to one, since gate AND8 has closed by lowering the Buslnl signal.

Figure 9 shows what happens if within a time interval Tin = C4 * R9 = 60 s, from the insertion of a plug in section one, a plug is inserted in section 3 of the invention. The CODEC of section 3 sends the signal of Plgln3 [plug in], but [see figure 6] does not set the LATCHCTRL since it finds gate AND7 closed having been the signal Slv [Slave] raised after the insertion of the first plug. By remaining reset [to zero] the LATCHCTRL, the socket of the section will act as a slave, leaving the writing signal W3 low. This is because nothing is written in the register of a slave section. The Busln3 signal is, on the other hand, brought to a high level and in this way a one will be written in bit number 3 [corresponding to section 3], but in the REGI register, that of the section that will act as master [the one since it has been inserted there the first plug]. If other plugs are inserted into the sockets of the invention before one minute has elapsed from the insertion of the first, the operation of their devices will be programmed as a slave of the first.

Figure 10 shows, in fact, what happens if a plug is inserted into the socket of section 12 before the time Tin = C4 * R9 = 60 s has elapsed, from the insertion of the plug of the device that will act as master into the socket of section 1 As you can see, the result is that in bit number 12 of the register

REGI is written a one, indicating that the twelfth trick, along with the second, acts as a slave to the first trick.

Figure 11 shows what happens after the time interval τίη. The signals go to zero but a one remains stored in both bit number 3 and bit number 12 of the REGI.

Figure 12 shows what happens if at this point a plug is inserted into the socket of section 2. The LATCHCTRL of section 2 [see figure 6] is set to 1 thus memorizing that it is a master device, raises the bit of Slv [slave] of the ControlBus and enables the REG2 register of section 2 to be written by raising signal W2 to one.

Figure 13 shows the photograph of the situation in the event that no plug is subsequently inserted, after the one inserted in socket 2, into any free socket, for a time interval equal to Tm = 60 s. In this situation, the device inserted in the socket of section 2 will work in complete autonomy.

At the end of the programming phase with the situation shown in figure 13, let us now try to analyze the operation of the invention, remembering that the only latches set are LATCHCTRL1 and LATCHCTRL2, thus indicating that only sections one and two act as master [the section due, however, has no slaves since they have no one written in their REG register and will therefore work in complete autonomy].

Figure 14 shows the connections to the ControlBus and BusOut in detail. Suppose that the device connected to socket 1 is switched on, the signal Cur [see figures 3, 4 and 5] will go high and CODEC 1 will send a CVar signal to CONTROL1 and a COn signal to the ControlBus so that all the CODECs of the twelve sections will receive the COn signal. Since section 1 has been programmed as master, the LATCHCTRL [see figure 6] is set and gate AND11 is open, therefore, the reading signal RI, sent to register REGI, becomes high, making it so that on BusOut the content of the REGI register is shown, in addition, the Read bit of the ControlBus, received by all twelve sections, is raised. In this way, each of the twelve sections reads from the REGI register of section 1, programmed as master, but only the sections that have been programmed as slave of section 1 read there, in the bit corresponding to the respective section, a 1. Since the signal Read high for all sections, the slave sections, which read a high bit in REGI, have a high BusO signal [see Figure 6], which finds AND10 gate open and generates a high Enb signal. The sections that have not been programmed as a slave of the section read a zero in the REGI and do not transmit the enable signal Enb to their CODEC. The high Enb signal is transmitted to the CODEC [see figure 5] and enables the LATCH, which is set to one since the COn output is high and thus, the Rei output becomes low, causing the contacts of the RL relay to close [see figure 3] of sections 3 and 12, and thus turning on the devices connected therein. All this is schematically represented in figure 14.

Figure 15 shows the status of the programmable control system, after the time T0n = C2 * R7 = ls, since the device connected to section 1 was switched on. COn and CVarl go low and [see Figure 6] the AND gate 11 closes by lowering the signals RI and Read. The output of the register REGI becomes high impedance by disconnecting it from the BusOut and all the bits of the BusOut are brought to a low level by the pull-down resistors R13 [see figure 6]. The lowering of the reading signal Read causes the lowering of all the enable signals Enb.

Figure 16 shows what happens if the device connected to the socket in section 1 switches off. The Curi signal becomes low and consequently the COff and CVarl signals become high for a period of time approximately equal to T0ff = C3 * R8 = ls [see Figure 5). Since section 1 has been programmed as master, the LATCHCTRL has been set to 1 [see figure 6] and, therefore, the AND gate11 is open and this brings to a high level the reading signal RI of the register REGI and the signal Read of the ControlBus. Consequently, the content of the REGI register appears on BusOut and each section reads the bit that concerns it. Sections 3 and 12 read a high value in the REGI and having the AND gate 10 open [see Figure 6], they send a high enabling signal Enb to the respective CODECs. The enabling signals enable the respective LATCHs which are reset since the COff signal is high, and consequently the Rel2 and Rell2 signals become high, sending the respective transistors T to saturation, which excites the relays RL inherent in the third and twelfth section. of the invention, turning off the devices whose operation has been programmed as a slave of the device connected to the first section.

7. METHOD OF INDUSTRIAL APPLICATION

The way in which the invention can be used in the industrial field is obvious from the nature of the invention and from the description.

8. PROPOSED CLASSIFICATIONS

The proposed European classification is as follows:

G06F1 / 32P2.

Claims (10)

CLAIMS of the patent application for industrial invention with TITLE: "PROGRAMMABLE MULTIPLE ELECTRIC SOCKET". 1. Multiple electrical socket having, inside the container in which it is housed, an electronic, logical and programmable system for the automatic control of the electrical connection of the sockets to the power source and characterized by the following: programming of the logic system control is done by connecting the electrical plugs of the users to the electrical sockets of the multiple electrical socket. 2. Multiple electrical socket as in claim 1 and characterized by the possibility of programming the operation of a selected combination of sockets in master slave mode, meaning, by master-slave mode, there is an electric socket called master and one or more sockets called slave of the master socket and that all slave sockets are connected to the source of electricity if and only if a current intensity above a certain value set as a threshold is absorbed from the master socket. 3. Multiple electrical socket as in claim 2 and characterized by the possibility of programming the operation of a selected combination of one's sockets in slave mode of more than one master, meaning, by slave mode of more than one master that, the socket said slave is disconnected from the electricity network, only if, at the same time, a current intensity below a certain value set as a threshold is absorbed by all the said master sockets, however, the slave socket is connected to the electricity network when at least one of the sockets said master is absorbed an intensity of current above a certain value set as a threshold. 4. Multiple electrical socket as in claim 3 and characterized by the following: the programming of the operation in master-slave mode of any selected combination of plug-free sockets, for a given group of electrical users, is done by connecting first, to a socket belonging to the selected combination, the plug of the electric user chosen as master and subsequently connecting to the selected combination of sockets, within a predetermined time interval and in any sequence, all the plugs of the users who will act as a slave to the first selected as master, allowing at least the aforementioned predetermined time interval to elapse completely, before connecting plugs of users not belonging to the aforesaid determined group of electrical users, for which operation in master-slave mode is being programmed. 5. Multiple electrical socket as in claim 3 and characterized by the following: the programming of operation in master-slave mode of any selected combination of plug-free sockets of the invention, for a given group of users, is done by connecting first, in the selected combination of free sockets and in any sequence, the plugs of the users chosen as slave and subsequently, within a predetermined time interval from the connection of the first plug, in the only socket left free of the selected combination of sockets, the plug of the user who will act as master, allowing at least the aforementioned predetermined time interval to pass completely, before connecting plugs of users not belonging to the aforementioned determined group of users, whose operation is being programmed in master-slave mode. 6. Multiple electrical socket as in claim 4 or in claim 5 and characterized by the possibility of programming the operation in master-slave mode, for more than one combination of sockets, repeating the operation of programming the operation of the combinations of sockets in master-slave mode , for each group of users that you want to operate in this mode, having as a limit to the connection of further groups, only Γ exhaustion of the plug-free sockets. 7. Multiple electrical socket as in claim 6 and characterized by the possibility of programming the operation of any socket free from plugs so that the electric user connected to it functions completely independently from the other users connected, programming this operating mode called autonomous, simply by connecting in the selected free socket, the user's plug intended to function autonomously and allowing a predetermined interval of time to pass before inserting another plug into any other socket. 8. Multiple electrical socket as in claim 7 and characterized by the fact that the programming of the operation of a socket in slave mode of more than one master is done by connecting the plug of the selected user who will act as a slave for more than one master, within a certain time interval from the connection of the plug of the first user who will act as master, and subsequently, repeating the programming operation, disconnecting and reconnecting, in the same socket, the plug of the user who will act as slave of more than one master, within a certain time interval from the insertion of the plug of the user who will act as master of a certain group of users operating in master-slave mode, an operation to be repeated every time the operation of a group of users in master-slave mode is programmed a master who wants to be associated with the chosen socket operating in slave mode of more than one master one. 9. Multiple electrical socket as in claim 8 and characterized by the possibility of canceling from the programming the operation of: any combination of sockets operating in master-slave mode, simply by disconnecting all the plugs of the connected group of users operating in master-slave mode; any socket that works independently from the other sockets, simply by disconnecting the user plug connected to it. 10. Multiple electrical socket as in claim 9 and characterized by the possibility of canceling from the programming the operation of any combination of sockets operating in the slave mode of more than one master, by disconnecting the plug of the user operating in the slave mode of more than one master. and the plugs of all users of the connected user groups operating in master-slave mode that have a master associated with the operation of the slave socket of more than one master.