BE1022218B1 - MODULE FOR DETERMINING THE ENERGY CONSUMPTION OF CONSUMERS CONNECTED TO A AUTOMAT, USE OF SUCH MODULE AUTOMATIC AND DIVISION BOX - Google Patents

Abstract

Module for determining the energy consumption of consumers connected to a machine (2), which module (4) is equipped with a meter (12) between the outputs (5) of the machine (2) and the consumers that is connected to a power supply (15), which meter (12) generates a signal depending on consumption, whereby the dimensions of the module (4) are such that the module (4) fits on the aforementioned output (5) and that the module (4) ) is provided with connections (9) between the outputs (5) of the machine (2) and outputs (7) for connecting consumers to the machine (2), whereby the power supply (15) is integrated in the module (4) and current can draw from the connections (9).

Description

Module for determining the energy consumption of consumers connected to a machine, use of such a module, machine and distribution box.

The present invention relates to a module for determining the energy consumption of consumers that are connected to an automatic device of an electrical installation.

It is known that in a building such as, for example, a house, a hospital, a company or the like, there is an electrical installation that consists of various electrical consumers that are often accommodated in so-called groups.

These groups may, for example, concern all electrical consumers of a particular room or room of the building, or may concern all light points or sockets of a part of the building.

A distribution box, also referred to as a distribution device or group box, ensures the distribution of the electricity from the electricity grid among the different groups.

In the distribution box, for each group, an installation automaton or, in short, an automaton is provided that will interrupt the electrical circuit of the group of consumers connected to the automaton if, for example, a short circuit or overload occurs in the relevant group.

It is also known that one wants to monitor the energy consumption, not only of the entire electrical installation, but also per machine, that is per group of consumers connected to a machine.

Modules already exist to determine the energy consumption of consumers connected to a machine of an electrical installation, which modules can determine the energy consumption of a group by determining the consumption via the machine and generating a pulse per consumption unit. The generated pulses can be read out by a pulse reader and the energy consumption can be measured on this basis.

The known installations have the disadvantage that such modules take up a lot of space, as a result of which they often cannot be integrated into the existing distribution box due to lack of space.

An additional distribution box must then be provided, or the existing distribution box must be replaced by a larger model. However, there is not always room for this.

In addition, additional (electrical) connections must be made between the different modules and automatons.

This makes the installation of the modules more expensive and difficult so that it becomes the job for a specialized professional who has the necessary tools and knowledge.

This also ensures that the distribution box forms an unclear and complicated set of wires, modules, circuit breakers and other types of switches.

This has the consequence that it is no longer possible for the user, such as for example the resident, to carry out small repairs, maintenance or changes to the distribution box, simply because there is no overview of the chaos in the distribution box.

The present invention has for its object to provide a solution to at least one of the aforementioned and other disadvantages.

To this end, the invention relates to a module for determining the energy consumption of consumers connected to a circuit-breaker of an electrical installation, which module is provided with a meter which is provided between the outputs of the circuit-breaker and the consumers and which is connected to a power supply, which meter generates a signal that can be read out via a signal output in function of the consumption, the dimensions of the module being such that the module fits on or can be integrated into the output of the machine and that the module is provided with connections between the outputs of the machine and outputs for connecting the aforementioned consumers to the machine where the power supply is integrated in the module, whereby the power supply can draw current from the aforementioned connections.

The meter may, for example, be a microprocessor or the like.

Such a module will allow to determine the energy consumption of the consumers by reading the generated signal.

An advantage is that due to the fact that the power supply is taken from the aforementioned connections, the power supply can be integrated into the module and can be made much more compact.

In this way the module can be connected directly to the machine.

This has the advantage that all necessary or desired modules can be fitted in the existing distribution box.

In addition, fewer electrical connection wires are required and the distribution box remains clear.

The installation of a module will also be very easy.

Preferably, the meter of the module can determine the energy generated by the consumers connected to a circuit-breaker, the signal that the meter generates being positive pulses with a positive voltage when energy is used and negative pulses with a negative voltage when energy is generated or vice versa.

This has the advantage that not only consumption but also generated energy can be determined, for example by solar panels or the like that are connected to a machine.

According to a preferred feature of the invention, when no power is supplied from the electricity grid to the electrical installation or when the circuit breaker has interrupted the circuit of the group, the meter generates interference pulses with a voltage lower than the voltage of the aforementioned pulses .

This has the advantage that when the consumers are without power, this is immediately or almost immediately detected.

This is important, for example, in hospitals, rest homes or the like, where the failure of electrical appliances can have disastrous consequences. This can range from a ventilator to cooling for the storage of, for example, donor blood.

The invention also relates to an automatic device provided with a module according to the invention, which module is integrated in the automatic device.

Such a vending machine can easily be integrated into a distribution box without taking up too much space.

The invention also relates to the use of a module according to the invention to determine the current energy consumption by measuring the time between two pulses or to determine the kilowatt hour by determining the number of pulses per hour.

The invention also relates to a distribution box of an electrical installation with at least one automatic device, wherein at least one automatic device is provided with a module according to the invention.

With the insight to better demonstrate the features of the invention, a preferred embodiment of a module according to the invention, its use, an automatic device and a distribution box, with reference to the accompanying drawings, is described below as an example without any limiting character. , wherein: figure 1 schematically represents a distribution box of an electrical installation; figure 2 schematically represents an automaton of the distribution box of figure 1; figure 3 represents the automaton of figure 2, but with the module disconnected; figure 4 schematically represents the internal structure and structure of the module of figure 3; figure 5 schematically represents a variant of figure 4, for a module adapted for a three-phase automatic.

Figure 1 schematically shows a distribution box 1 of an electrical installation. In the distribution box 1 are a number of automatons 2 which are mounted on rails 3.

Each machine 2 is connected to a number of electrical consumers, which are not shown here.

In this example, each machine 2 is connected to a module 4 according to the invention for determining the energy consumption of the consumers connected to the relevant machine 2.

The dimensions of the module 4 are in this case such that it fits on the output 5 of the machine 2. The module 4 can be considered as a sort of attachment.

It is clear that not every machine 2 must be provided with such a module 4, but, for example, only those machines 2 for which it is desired to determine the consumption, at least of consumers connected to it.

Figures 2 and 3 show a vending machine 2 with a module 4 in more detail, while in Figure 3 the vending machine 2 is disconnected from the module 4. The machine 2 is a standard machine 2 and in other words is not adapted to be able to fit the module 4.

As can be seen in figure 3, the machine 2 is provided with an output 5 to which the consumers can be connected.

The module 4 is provided with two pins 6 which are suitable for the output 5 of the machine.

The module 4 is also provided with outputs 7 for connecting the aforementioned consumers, so that the consumers can be connected to the machine 2 via these outputs 7 of the module 4.

The module 4 is also provided with a signal output 8.

Figure 4 schematically shows the internal structure and structure of the module 4 of Figure 3.

In this figure the two pins 6 are shown schematically for the connection of the module 4 to the output 5 of the automatic device 2.

It can further be seen that the module 4 is provided with connections 9 between the pins 6 and the outputs 7 for connecting the consumers.

A current meter 10 and a voltage meter 11 are also provided which determine the current I through and the voltage U across the aforementioned connections 9, respectively.

The signal from the current meter 10 and the voltage meter 11 is coupled by a meter 12.

This meter 12 may, for example, be a microprocessor which is designed to determine the energy consumption of the consumers connected to the machine 2 on the basis of the determined current I and voltage U.

The microprocessor will generate a signal as a function of consumption which is sent to an optocoupler 13.

The opto-coupler 13 has a signal output 8 which can be read with a signal reader 14. Figure 1 shows how the signal output 8 of each module 4 is coupled to a signal reader 14.

The opto-coupler 13 provides the coupling with or the signal transfer to the signal reader 14, the opto-coupler 13 ensuring that interference or electrical feedback can occur between the meter 12 or module 4 on the one hand and the signal reader 14 on the other .

The signal output 8 preferably has no polarity, so that the connection to a signal reader 14 cannot go wrong and is possible to any signal reader 14.

According to the invention, the module 4 is provided with an integrated power supply 15, wherein the power supply 15 can draw current from the aforementioned connections 9. In other words: the power supply 15 for the meter 12 comes via the automatic device 2.

To this end, the power supply 15 is provided, for example, with a dissipation-free converter for setting the voltage to a suitable voltage for the meter 12.

Due to this integration, the module 4 can be made very compact and, as can be seen in Figure 2, the dimensions are such that the shape of the module 4 corresponds to that of the machine 2, so that the whole of module 4 and machine 2 is a compact forms a whole that can easily be fitted in an existing distribution box 1.

The operation and use of the module 4 is very simple and as follows.

Consumers connected to the machine 2 will consume electrical power, which will pass through the connections 9 along the module 4.

The current meter 10 and the voltage meter 11 determine the current I and the voltage ü respectively and send their signal to the meter 12.

The meter 12 will determine the energy consumption based on these signals according to the formula: P = U * I * cos (y), where: P represents the determined energy consumption; ü the voltage determined by the voltage meter 11, the current determined by the current meter 10 and cos (y) is a measure of the phase difference between the current I and the voltage U.

The meter 12 and thus the module 4 are preferably adapted for voltages between 110 Volts and 230 Volts. These are standard voltages for electrical installations of buildings and the like.

The meter 12 in this example is adapted for currents between 0 and 20A, so that the module 4 is adapted for a standard electrical installation of a house.

It is of course not excluded that the meter 12 is adapted for currents between 0 and 80A, so that the module 4 is also suitable for applications in an industrial electrical installation.

In order to provide the meter 12 with the necessary current, the power supply 15 will draw current from the aforementioned connections 9, the inverter converting the voltage to an appropriate value for the meter 12.

Based on the determined energy consumption, the meter 12 will generate a signal.

These are preferably pulses, wherein a pulse is generated per consumption unit. The consumption unit is understood here to mean a unit of consumption.

This consumption unit is preferably between 0.01 Watt and 10 Watt and is preferably 0.2 Watt. This means that the meter generates a pulse per 0.2 Watt consumption unit.

It is clear that the size of the consumption unit depends on the expected consumption and the desired accuracy of the measurements.

According to an aspect of the invention, it is possible that the meter 12 is adapted to determine the energy generated by the devices connected to the machine.

This can be useful when, for example, solar panels or the like are connected to the machine 2.

Preferably, the meter will generate 12 positive pulses, i.e. pulses with a positive voltage, when energy is consumed.

When energy is generated by the devices, negative pulses will be generated, that is, pulses with a negative voltage.

In the example shown, the signal output 8 is provided for this: there are three sub-signal outputs 8: one neutral or grounding 8a, one positive 8b for the positive pulses and one negative 8c for the negative pulses.

The generated pulses are transmitted via the optocoupler 13 to the signal reader 15, in this case a pulse reader 15.

The pulse reader 15 will process the pulses in order to determine the energy consumption from the pulses.

The module 4 can on the one hand be used to determine the current energy consumption, because the pulse reader 14 measures the time between two pulses.

On the other hand, the module 4 can also be used to determine the kilowatt hour by determining the number of pulses per hour.

For this, the pulse reader 15 will count the number of pulses per time unit and convert this to the number of pulses per hour.

In addition to these two functionalities, the module 4 with the pulse reader 15 can also be adapted to perform a third function.

By setting the meter 12 so that interference pulses are generated with a voltage lower than the voltage of the aforementioned positive and negative pulses, when no electricity is supplied from the electricity grid to the electrical installation or when the circuit breaker 2 is the circuit of the group has been interrupted, it can be determined when the consumers are not receiving power.

This may be of interest to certain consumers such as, for example, medical equipment, cooling devices or the like, where rapid detection of the lack of power is crucial.

Figure 5 shows a variant of Figure 4, wherein the module 4 is adapted for a three-phase automatic 2.

As can be seen in this figure, the module 4 is equipped with a meter 12, a current meter 10 and a voltage meter 11 for each phase, so that the module 4 can measure the energy consumption for each phase.

Each meter 12 has a signal output 8, so that the module 4 in this case has three signal outputs 8, one for each phase. The three signal outputs 8 are connected to a signal reader 14, where the energy consumption of the three-phase can be added.

For the rest, the operation is analogous to the embodiment described above.

Although in the examples shown above the module 4 is mounted on the machine 2, it is not excluded that the module 4 is integrated in the machine 2, that is, the module 4 is built into the housing of the machine 2.

The machine 2 will then be provided with a signal output 8, in addition to the output 7 for the connection of the consumers.

It is also possible that one or more of such machines 2 are used in the distribution box 1, whether or not in combination with the machine 2 as shown in figure 2.

The present invention is by no means limited to the embodiments described as examples and shown in the figures, but of a module according to the invention, its use, an automatic device and a distribution box can be realized in all kinds of variants without departing from the scope of the invention .

Claims (16)

Conclusions. 1. - Module for determining the energy consumption of consumers connected to an automatic device (2) of an electrical installation, which module (4) is provided with a meter (12) that is connected between the outputs (5) of the automatic device ( 2) and the consumers are provided and which are connected to a power supply (15), which meter (12) generates a signal as a function of consumption which can be read out via a signal output (8), characterized in that the dimensions of the module (4) is such that the module (4) fits on or can be integrated into the output (5) of the machine and that the module (4) is provided with connections (9) between the outputs (5) of the circuit breaker (2) and outputs (7) for connecting the aforementioned consumers to the circuit breaker (2) where the power supply (15) is integrated in the module (4), whereby the power supply (15) can draw current from the aforementioned connections ( 9). Module according to one of the preceding claims, characterized in that the signal that the meter (12) generates are pulses, a pulse being generated per unit of consumption. Module according to claim 2, characterized in that the size of the consumption unit is between 0.01 Watt and 10 Watt and is preferably 0.2 Watt. Module according to one of the preceding claims, characterized in that the module (4) is provided with a current meter (10) and a voltage meter (11) which passes the current (I) through the voltage (U) over the above-mentioned determines connections (9), the signal from the current meter (10) and the voltage meter (11) being coupled to the meter (12), the meter (12) determining the energy consumption according to the formula: P = U * I * cos (y), wherein: P represents the determined energy consumption; U is the voltage determined by the voltage meter (11), I is the current determined by the current meter (10) and cos (y) is a measure of the phase difference between the current (I) and the voltage (U). Module according to one of the preceding claims, characterized in that the meter (12) of the module (4) can determine the energy generated by the consumers connected to an automatic device (2), the signal being the meter (12) generates positive pulses with a positive voltage when energy is consumed and negative pulses with a negative voltage when energy is generated or vice versa. The module according to any of the preceding claims 2 to 5, characterized in that when no power is supplied from the electricity grid to the electrical installation or when the circuit breaker (2) has interrupted the consumer circuit, the meter (12) ) generates interference pulses with a voltage lower than the voltage of the aforementioned pulses. Module according to one of the preceding claims, characterized in that the module (4) is provided with an optocoupler (13) which is connected to the signal output (8) of the module (4) and ensures the coupling with a signal reader (14). Module according to one of the preceding claims, characterized in that the module (4) is adapted for voltages between 110 volts and 230 volts. The module according to any of the preceding claims, characterized in that the module (4) is adapted for currents between 0 and 20 A. The module according to any of the preceding claims 1 to 8, characterized in that the module (4) is adapted for currents between 0 and 80A. The module according to any one of the preceding claims, characterized in that the module (4) is adapted for a three-phase automaton (2), wherein the module (4) measures the energy consumption for each phase. The module according to any of the preceding claims, characterized in that the signal output (8) of the module (4) has no polarity and can be connected to any signal reader (13). A vending machine, characterized in that the vending machine is provided with a module (4) according to one of the preceding claims, which module (4) is integrated in the vending machine (2). Use of a module according to one of the preceding claims 2 to 12, characterized in that the module (4) is used to determine the current energy consumption by measuring the time between two pulses. Use of a module according to one of the preceding claims 2 to 12, characterized in that the module (4) is used to determine the kilowatt hour by determining the number of pulses per hour. 16. Distribution box of an electrical installation with at least one automatic device, characterized in that at least one automatic device (2) is provided with a module (4) according to one of the preceding claims 1 to 12. Distribution box according to claim 16, characterized in that the module (4) is integrated in the machine (2).