FR3002809A1 - Display unit for displaying illuminated products containing perfume in e.g. airport, has protection elements to protect power supply device against electric overcurrent, where each element is connected between voltage source and output plug - Google Patents

Abstract

The display unit (10) has a display structure (14) provided with a lighting unit (18) of products, and an a power supply device (16) supplying power to the lighting unit and including a voltage source (24) and two electric output plugs (26), where each plug is connected to the voltage source and to a power supply input plug (22) of the lighting unit. The power supply device includes protection elements (28) to protect the power supply device against an electric over current, where each protection element is connected between the voltage source and one of the output plugs.

Description

The present invention relates to a display of illuminated products, of the type comprising: - a product presentation structure, the presentation structure being provided with lighting means of the products, the means lighting system comprising at least two power supply input plugs, - a power supply device capable of supplying the lighting means with electrical energy, the power supply device comprising a voltage source and at least two output electrical plugs, each output plug being connected on the one hand to the voltage source and on the other hand to a power supply input plug of the lighting means. The field of the invention is that of electrical lighting systems.

In particular, the invention relates to electric lighting systems for illuminating display structures of products at the point of sale, in particular lighting systems based on light-emitting diodes. A display of the aforementioned type is known. Such a display is used in a public place for the presentation of products at the point of sale. When an electrical short circuit occurs within the presentation structure, one of the output electrical plugs of the power device is short-circuited. Due to the electrical connection between this output plug and the voltage source of the supply device, the latter is also short-circuited. This results in a strong current draw on the voltage source, resulting in a consequent increase in the current delivered by the voltage source in the shorted output plug. When the current flowing through the connector connecting the shorted output plug to the input plug of the associated presentation structure reaches the current specification limit value of that connector, the latter is heated by Joule effect, resulting in a risk of fire in the environment close to the connector.

To avoid this phenomenon, a known solution consists in using as a voltage source a voltage supply equipped with an integrated electrical protection system. Such a system makes it possible to cut off the current supply when the current called by one of the output plugs exceeds a nominal value of the current, such a nominal value being preimplanted within the protection system. However, this solution leads to the stopping of the power supply supplied on each of the output plugs. Thus, the non-shorted output plugs are no longer supplied with current. No current therefore feeds the input plugs of the lighting means of the presentation structure, and these are completely out of service the time of the removal of the electrical short circuit. An object of the invention is therefore to provide an illuminated product display allowing, in the event of short-circuiting of one of the output plugs of the power supply device, to limit the short-circuit current and the rise. in consecutive temperature within the display, while maintaining a degraded operating mode in which the non-shorted output plugs remain in service. For this purpose, the subject of the invention is a display unit of the aforementioned type, in which the power supply device comprises at least two electrical overcurrent protection members, each protection member being connected between the voltage source and one of the output cards. According to other embodiments, the display unit comprises one or more of the following characteristics, taken individually or in any technically possible combination: each electrical protection member is an electrical cut-off device capable of opening and closing a electrical circuit ; each electrical protection member comprises a resettable fuse; each electrical protection element comprises a resistor connected between the voltage source and one of said output plugs, and a threshold voltage detector connected in parallel with the resistor, the threshold voltage detector comprising at least one switching element galvanic isolation; each electrical protection member is capable of limiting the value of the intensity of the current flowing in the output plug connected to said electrical protection member, so that said value of the intensity of the current does not exceed a predetermined value; ; each electrical protection member comprises an integrated electronic circuit provided with three electrodes, and a resistor, the integrated electronic circuit being connected by one of its electrodes to the voltage source, the resistance being connected on the one hand to the other two electrodes of the integrated electronic circuit, and secondly to said output plug, the integrated electronic circuit being adapted to limit the value of the intensity of the current flowing in said output plug; each electrical protection element comprises a voltage comparator with two inputs, a first bipolar transistor and a second bipolar transistor; the presentation structure comprises several product presentation shelves, and in that the lighting means comprise at least two lighting elements and a number of power supply input plugs equal to the number of shelves of the presentation structure, each shelf being intended to be illuminated by a lighting member connected to an associated power input plug; the ratio between the electrical power delivered on each output plug and the electrical power delivered at the output of the voltage source is limited by a maximum value of between 0.09 and 0.25, preferably substantially equal to 0.15. These features and advantages of the invention will appear on reading the description which follows, given solely by way of nonlimiting example, and with reference to the appended drawings, in which: FIG. 1 is a diagrammatic view of a display of products according to the invention, connected to an alternating electrical network, comprising six electrical overcurrent protection devices; FIG. 2 is an electrical diagram of one of the protection members of the display unit of FIG. 1, according to a first embodiment of the invention; FIG. 3 is an electrical diagram of a first variant embodiment of the protection element of FIG. 2; FIG. 4 is an electrical diagram of a second variant embodiment of the protection member of FIG. 2; FIG. 5 is a view similar to that of FIG. 2 according to a second embodiment of the invention; and FIG. 6 is a circuit diagram of an alternative embodiment of the protection element of FIG. 5. FIG. 1 represents a display rack 10 of products capable of receiving and illuminating the products. The display unit 10 is connected to an electrical network 12.

The electrical network 12 is, for example, a domestic single-phase reciprocating network, having a nominal voltage typically of the order of 260 V between phase and neutral, and a frequency for example equal to 50 Hz. The display unit 10 comprises a structure 14 of presentation of the products, including several shelves 15A carried by a frame 15B, and a power supply device 16 connected between the electrical network 12 and the presentation structure 14. In the embodiment of Figure 1, the presentation structure 14 has six presentation shelves 15A. In variant not shown, the presentation structure 14 does not include presentation shelves 15A. The presentation structure 14 comprises means 18 for illuminating the products.

The lighting means 18 comprise, for each shelf 15A, a lighting member 20, formed for example of a light emitting diode array connected to a clean power supply by an input plug 22 specific to the lighting member 20. Each input plug 22 is provided with two power supply input terminals, not shown, each lighting member 20 associated with an input plug 22 being connected between the two input terminals of this plug The illumination means 18 thus comprise a number of power supply input plugs 22 equal to the number of shelves 15A of the presentation structure 14. The power supply device 16 comprises a housing 23 inside which are arranged a voltage source 24 connected to the electrical network 12, and at least two output electric plugs 26. The power supply device 16 also comprises, in accordance with the invention, the two electrical overcurrent protection members 28 arranged in the housing 23. In the embodiment of FIG. 1, the power supply device 16 comprises six output plugs 26 and six protection members 28. The device Power supply 16 is suitable for supplying the lighting means 18 with electrical energy, as described below. The housing 23 is for example a metal housing. The voltage source 24 is for example a DC voltage source. The voltage source 24 comprises two input terminals 29A, 29B each connected to the electrical network 12, and two intermediate output terminals 30A, 30B. It comprises, for example, conventionally, a voltage transformer, a voltage rectifier associated with a filter, and a voltage regulator connected in series. The voltage source 24 thus forms a switching power supply, conventionally known. It delivers between its intermediate output terminals 30A, 30B a DC voltage value for example substantially equal to 12 V, and an electric power preferably between 120 W and 320 W, for example substantially equal to 200 W. Each record outlet 26 is provided with two output terminals 31A, 31B, as illustrated in FIGS. 2 to 6. Each output plug 26 is connected on the one hand to one of the input plugs 22 of the lighting means 18, via a double connector 32, and secondly to the voltage source 24, via one of the protection members 28. More specifically, each output plug 26 is connected to one of the protection members 28 by means of a double wire connection 34, as detailed later. Each double wired link 34 comprises two wired connectors 36A, 36B, as illustrated in FIGS. 2 to 6. Each protection member 28 is connected between the voltage source 24 and one of the output plugs 26. As shown in FIGS. 4, each protection member 28 comprises two arms 38A, 38B. A first arm 38A of the protection member 38 is connected between a first intermediate output terminal 30A of the voltage source 24, and a first output terminal 31A of the associated output plug 26. More specifically, the first arm 38A is connected to the first output terminal 31A via a first wired connector 36A of one of the double wire links 34.

A second arm 38B of the protection member 38 is connected between a second intermediate output terminal 30B of the voltage source 24, and a second output terminal 31B of the associated output plug 26. Specifically, the second arm 38B is connected to the second output terminal 31B via a second wired connector 36B of the dual wire link 34.

In the embodiment of FIG. 2, each protection member 28 advantageously comprises, on its first arm 38A, a resettable fuse 40. The resettable fuse 40 is for example formed of a resistor with a positive ohmic temperature coefficient, presenting a tilting current of value for example substantially equal to 2.5 A. As known per se, the resettable fuse 40 is thus able to open the electrical circuit consisting of the first and second arms 38A, 38B and the lighting member 20 associated with a current greater than 2.5 A through, and is able to close this electrical circuit when the current drops below 2.5 A. According to an alternative embodiment shown in Figure 3, each fuse resettable 40 is replaced by a cell 42. The cell 42 comprises a resistor 44, and a threshold voltage detector 46. The resistor 44 is arranged on the first arm 38A of the associated protection member 28. t has a value for example substantially equal to 0.05 0. The threshold voltage detector 46 is connected in parallel with the resistor 44. It comprises a member 48 for detecting a voltage across the resistor 44 and at least a galvanically isolated switching member 50. In the embodiment of FIG. 3, the threshold voltage detector 46 comprises a single galvanically isolated switching element 50, electrically connected to the detection element 48. In this embodiment, FIG. embodiment, the detection member 48 is a voltage comparator operational amplifier. The non-inverting input of the operational amplifier 48 is connected to one of the terminals of the resistor 44, the inverting input being connected to the other terminal of the resistor 44. The operational amplifier 48 is configured so that it has a non-zero internal offset voltage. In the embodiment of FIG. 3, the operational amplifier 48 has an internal offset voltage of absolute value, for example substantially equal to 0.125 V.

The electrically isolated switching element 50 comprises a switch 52 and an actuator 54, mechanically connected to the switch 52. In the embodiment of FIG. 3, the galvanically isolated switching member 50 is an electromechanical relay. and the actuator 54 is an electromagnet.

The switch 52 is arranged on the second arm 38B of the associated protection member 28. The switch 52 is movable between an open position and a closed position and is able to pass from its closed position to its open position, and vice versa, under the mechanical control of the electromagnet 54. The electromagnet 54 is electrically connected between the output of the operational amplifier 48 and one of the terminals of the switch 52. As known per se, the electromagnet 54 is able to control, according to the sign of the signal output of the operational amplifier 48, the opening or closing of the switch 52. In a variant not shown, the switching element with galvanic isolation 50 is a static relay. The actuator 54 is then an optocoupler, optically connected to the switch 52. The switch 52 is, according to this variant, a semiconductor component, such as a transistor for example, whose electrical state is adapted to pass from a blocked state to an on state, and vice versa. In another variant, the switching element with galvanic isolation 50 is replaced by a transistor, for example a bipolar transistor. The collector, respectively the emitter, of the bipolar transistor is connected, on the second arm 38B, to the second intermediate output terminal 30B of the voltage source 24, respectively to the second output terminal 31B of the output plug 26 associated. The base of the bipolar transistor is connected to the output of the operational amplifier 48. According to another variant embodiment shown in FIG. 4, the threshold voltage detector 46 comprises the detection element 48, a diode 55, a first switching element with galvanic isolation 56 and a second switching element with galvanic isolation 58. The anode of the diode 55 is connected to the output of the operational amplifier 48. The cathode of the diode 55 is connected to the first switching element with galvanic isolation 56, as detailed below. The first electrically isolated switching device 56 comprises a first switch 60 and a first actuator 62, mechanically connected to the first switch 60. In the embodiment of FIG. 4, the first galvanically isolated switching element 56 is a relay electromechanical and the first actuator 62 is an electromagnet.

The first switch 60 is arranged on the second arm 38B of the associated protection member 28. The first switch 60 is movable between an open position and a closed position and is adapted to move from its closed position to its open position, and vice versa, under the mechanical control of the first electromagnet 62. first electromagnet 62 is electrically connected between the cathode of the diode 55 and an electrical ground. The first electromagnet 62 is capable of controlling the opening or closing of the first switch 60. The second electrically isolated switching element 58 comprises a second switch 64 and a second actuator 66, mechanically connected to the second switch 64. embodiment of Figure 4, the second electrically isolated switching member 58 is an electromechanical relay and the second actuator 66 is an electromagnet. The second switch 64 is electrically connected between the non-inverting input of the operational amplifier 48 and the cathode of the diode 55. The second switch 64 is movable between an open position and a closed position and is adapted to move from its closed position to its open position, and vice versa, under the mechanical control of the second electromagnet 66. The second electromagnet 66 is arranged on the second arm 38B of the associated protection member 28, and is connected between the first switch 60 and the second output terminal 31 B of the associated output plug 26. The second electromagnet 66 is capable of controlling the opening or closing of the second switch 64. The terminal of the second electromagnet 66 connected to the second output terminal 31 B of the associated output plug 26 is also connected to the terminal of the second switch 64 connected to the non-inverting input of the operational amplifier 48. In the first embodiment of the invention, each protection member 28 is an electrical switching device capable of opening and closing an electrical circuit . More specifically, each protection member 28 is able to open the electrical circuit when a current of intensity greater than 2.5 A flows within it.

The operation of the display 10 according to the invention will now be explained. One of the protection members 28, as well as the output plug 26, the double connector 32, the input plug 22 and the lighting member 20 associated with this protection member 28 are considered thereafter. a current of intensity less than or equal to 2.5 A flows within the protection member 28, this current firstly coming from one of the two intermediate output terminals 30A, 30B of the voltage source 24 passing through one of the two arms 38A, 38B of the protection member 28, circulating within the lighting member 20 and then through the other of the two arms 38A, 38B, and finally joining the other output terminal intermediate 30A, 30B. It is assumed that at a first given moment, a fault occurs, for example an electric short-circuit-type defect on the side of the presentation structure 14, at the level of the lighting member 20. The voltage source 24 is then short-circuited. This results in a strong current draw on the voltage source 24, which causes a consequent increase in the current delivered by the voltage source 24. The current flowing in the protection member 28 increases, until it is present. an intensity value greater than 2.5 A. The protection member 28 then opens the electric circuit from a second moment. This isolates the associated output plug 26 and plug 22 from the rest of the electrical assembly. The other output plugs 26, and consequently the other lighting members 20, are always supplied with current by the voltage source 24. In addition, the current flowing in the associated double connector 32 decreases sharply, without having reached the current specification limit value of this connector 32. In the embodiment of Figure 2, between the first and second instants, as soon as the current flowing in the protection member 28 has an intensity value higher than 2.5 A, the increase of the resistance forming the resettable fuse 40 is such that the electric circuit opens. Once the electrical circuit is open after the second instant, the intensity of the current flowing in the protection member 28 decreases and falls below 2.5 A from a third instant. The resettable fuse 40 then closes the electrical circuit, then adopts an oscillating speed between opening and closing of the electrical circuit, as long as the electrical fault is not repaired.

In the variant embodiment of FIG. 3, between the first and second instants, as soon as the current flowing in the protection element 28 has an intensity value greater than 2.5 A, the sign of the output signal of the operational amplifier 48 changes. The electromagnet 54 then controls the opening of the switch 52. As for the previous embodiment, the intensity of the current flowing in the protection member 28 then decreases and goes down below 2.5 A from a third moment. As long as the electrical fault is not repaired, the threshold voltage detector 46 thus adopts an oscillating speed between opening and closing of the electrical circuit, via the switch 52. In the variant embodiment of FIG. and second instants, as soon as the current flowing in the protection member 28 has an intensity value greater than 2.5 A, the sign of the signal at the output of the operational amplifier 48 changes. The first electromagnet 62 then controls the opening of the first switch 60. The current flowing in the second electromagnet 66 then vanishes, causing the second switch 64 to close. The current supplied by the voltage source 24 and passing through the first arm 38A of the protection member 28 then flows within the second switch 64 to the electrical ground of the device, via the first electromagnet 62. Thus, the current flowing in the body of the protection 28 remains substantially constant, and has an intensity value greater than 2.5 A. The sign of the output signal of the operational amplifier 48 does not change. Therefore, unlike the two previous embodiments, the protection member 28 keeps the electrical circuit open after the second time, as the electrical fault is not repaired. The protective member 28 according to this embodiment variant thus advantageously has a "memory" effect of the electrical fault. It is thus conceivable that the display unit 10 according to the invention makes it possible, in the event of short-circuiting of one of the output plugs 26 of the supply device 16, to limit the short-circuit current and the rise in temperature. consecutively within the display 10, while maintaining a degraded mode of operation in which the non-shorted output pins 26 remain in service. Each output plug 26 is thus independent of the electrical behavior of the other output plugs 26. The fact of limiting the rise in temperature within the various electrical components of the display rack 10 improves the overall safety of the installation, and makes it possible to enlarge Advantageously, the range of materials that can be envisaged for the presentation structure 14. In particular, plastic materials having a lower temperature resistance, which are not used in the prior art, can be used in the presentation structure 14 of the display unit 10 according to FIG. invention. This can be particularly advantageous, especially in environments for which special precautions are required regarding the flammability of materials, such as sales outlets of products containing perfume, in public places such as airports, pharmacies. etc. Furthermore, the display unit 10 according to the first embodiment of the invention makes it possible to prevent all the electrical power delivered by the voltage source 24 from being transferred to a single output plug 26, which also contributes to improving the In addition, compared to the display according to the second embodiment described below, the display 10 according to the first embodiment allows, via the structure of its protection members 28, to isolate the output plug 26 and the input plug 22 short-circuited from the rest of the electrical assembly. This avoids any subsequent destruction of these electrical connectors, as well as the lighting member 20 downstream. FIG. 5 illustrates a second embodiment of the invention, for which elements similar to those of the first embodiment described above are identified by identical references, and are therefore not described again. The power supply device 16 comprises six devices 70 for protection against electrical overcurrent. Each protection member 70 is connected between the voltage source 24 and one of the output plugs 26 and has two arms 38A, 38B.

In the embodiment of FIG. 5, each protection member 70 comprises a cell 73. The cell 73 comprises a voltage comparator 74 with two inputs, a first resistor 76, a first bipolar transistor 80, a second bipolar transistor 82 a second resistor 83, a third resistor 84, a fourth resistor 86, a fifth resistor 87 and a zener diode 88.

The voltage comparator 74 is for example formed of a voltage comparator operational amplifier. The first resistor 76 is connected on the one hand to the first intermediate output terminal 30A of the voltage source 24, and on the other hand to the non-inverting input of the comparator 74 at a first connection node 90. value for example substantially equal to 2 ka The collector of the first bipolar transistor 80 is connected to the first intermediate output terminal 30A of the voltage source 24. The base of the second bipolar transistor 82 is connected to the emitter of the first bipolar transistor 80 at a second connection node 92. The collector of the second bipolar transistor 82 is connected to the base of the first bipolar transistor 80 at a third connection node 94. The emitter of the second bipolar transistor 82 is connected to the first output terminal 31A of the associated output 26 card. The second resistor 83 is connected between the output of the comparator 74 and the third connection node 94. It has a value for example substantially equal to 5 kf). The third resistor 84 is arranged on the first arm 38A of the protection member 70. It is connected between the second connection node 92 and the first output terminal 31A of the associated output plug 26. The third resistor 84 has a value, for example substantially equal to 1 0.

The fourth resistor 86 is connected on the one hand to the inverting input of the comparator 74 in a fourth connection node 96, and on the other hand to the first output terminal 31A of the associated output plug 26. It has a value for example substantially equal to 240 0. The fifth resistor 87 is connected between the fourth connection node 96 and an electrical ground. It has a value for example substantially equal to 1 kc). The Zener diode 88 is connected between the first connection node 90 and the second intermediate output terminal 30B of the voltage source 24. The cell 73 is able to limit the value of the intensity of the current flowing in the output plug 26 associated, so that this value does not exceed a predetermined value. In the embodiment of FIG. 5, the values of the constituent electrical components of the cell 73 impose a predetermined value of the intensity substantially equal to 2.5 A. As a variant, each bipolar transistor 80, 82 is replaced by any controllable transistor, such as for example an IGBT transistor (English lnsulated Gate Bipolar Transistor) or a field effect transistor. The voltage delivered on the first output terminal 31A is variable and depends on the intensity of the current flowing in the third resistor 84. The higher the value of the intensity of the current flowing in the third resistor 84, the higher the the value of the voltage on the first output terminal 31A is low.

According to an alternative embodiment shown in FIG. 6, each cell 73 is replaced by an integrated electronic circuit 98 and a resistor 100. The integrated circuit 98 is arranged on the first arm 38A of the protection member 70 and is provided with an input electrode 102A, a reference electrode 102B, and an output electrode 102C.

The input electrode 102A is connected to the first intermediate output terminal 30A of the voltage source 24. The reference electrode 102B is connected to the first output terminal 31A of the associated output plug 26, at a point The resistor 100 is connected between the output electrode 102C and the connection point 104. It has a value for example substantially equal to 0.5 0. The integrated circuit 98 forms a current regulator capable of limiting the voltage. value of the intensity of the current delivered on its output electrode 102C. More specifically, the integrated circuit 98 is able to impose a reference voltage between the reference electrode 102B and the output electrode 102C, a maximum value substantially equal to 1.25 V.

The protection member 70 is thus able to limit the value of the intensity of the current flowing in the associated output plug 26, so that this value does not exceed a predetermined value. In the embodiment of FIG. 6, the predetermined value of the intensity is substantially equal to 2.5 A. Unlike the embodiment of FIG. 5, the voltage delivered on the first output terminal 31A is substantially constant. and is independent of the current flowing in the integrated circuit 98. The voltage drop between the first intermediate output terminal 30A of the voltage source 24 and the first output terminal 31A of the output plug 26 is related solely to the fall intrinsic voltage of the integrated circuit 98, the value of this voltage drop being known. This advantageously makes it possible to obtain a voltage between the terminals of the lighting element 20 that is substantially constant, whatever the intensity of the current supplied by the power supply device 16. The lighting element 20 in this variant of FIG. embodiment thus has an improved brightness compared to that of the lighting member 20 of the embodiment of FIG. 5. In the second embodiment of the invention, each protection member 70 is able to limit the value of the intensity of the current flowing in the output plug 26 connected to the protection member 70. More specifically, each protection member 70 is able to limit the value of the intensity of the current flowing in the associated output plug 26, so that this value does not exceed a value of the predetermined intensity.

In operation, when an electrical fault occurs on the side of the presentation structure 14, the voltage source 24 is short-circuited and the intensity of the current flowing within the protection member 70 increases. The intensity of this current reaches the predetermined value of 2.5 A at the second instant. From this second moment, the protection member 70 then limits the value of the intensity of the current to this predetermined value. Thus, the value of the intensity of the current flowing in the output plug 26 is limited, despite the presence of the electrical fault at the associated lighting member 20. The other output plugs 26, and therefore the other lighting members 20, are always supplied with current by the voltage source 24, and the current flowing in the associated double connector 32 remains substantially constant, without reaching the limit value. In addition to the advantages specific to overcurrent protection devices, the other advantages of this second embodiment of the display stand 10 are identical to those of the first embodiment, and therefore are not the same as those of the first embodiment. not described again.

In the first and second embodiments of the invention, the current delivered on each output plug 26 is limited by a maximum value. Therefore, the ratio between the electric power delivered on each output plug 26 and the electrical power outputted from the voltage source 24 is also limited by a maximum value. This maximum value is advantageously between 0.09 and 0.25. In the exemplary embodiments of FIGS. 1 to 6, the maximum value of the current delivered on each output plug 26 is substantially equal to 2.5 A and the maximum value of the power ratio is substantially equal to 0.15.

Claims (9)

CLAIMS1.- Display (10) of illuminated products, the display (10) comprising: - a structure (14) for presenting the products, the presentation structure (14) being provided with means (18) for lighting products, the lighting means (18) comprising at least two power supply input plugs (22), - a power supply device (16) capable of supplying the lighting means (18) with electrical energy, the device power supply unit (16) comprising a voltage source (24) and at least two output electric plugs (26), each output plug (26) being connected on the one hand to the voltage source (24) and on the other hand to a power supply input plug (22) for the lighting means (18), characterized in that the power supply device (16) comprises at least two protection elements (28; an electrical overcurrent, each protection member (28; 70) being connected between the source voltage connector (24) and one of the output plugs (26). 2. Display unit (10) according to claim 1, characterized in that each electrical protection member (28) is an electrical cutoff member adapted to open and close an electrical circuit. 3.- Display (10) according to claim 2, characterized in that each electrical protection member (28) comprises a resettable fuse (40). 4. Display stand (10) according to claim 2, characterized in that each electrical protection member (28) comprises a resistor (44) connected between the voltage source (24) and one of said output plugs (26), and a threshold voltage detector (46) connected in parallel with the resistor (44), the threshold voltage detector (46) having at least one galvanically isolated switching element (50; 56,58). 5.- display (10) according to claim 1, characterized in that each electrical protection member (70) is adapted to limit the value of the intensity of the current flowing in the output plug (26) connected to said protective member electric (70), so that said value of the current intensity does not exceed a predetermined value. 6. Display unit (10) according to claim 5, characterized in that each electrical protection member (70) comprises an integrated electronic circuit (98) provided with three electrodes (102A, 102B, 102C), and a resistor (100), the integrated electronic circuit (98) being connected by one of its electrodes (102A, 1028, 102C) to the voltage source (24), the resistor (100) being connected on the one hand to the two other electrodes (102A, 102B, 102C) of the integrated electronic circuit (98), and secondly to said output plug (26), the integrated electronic circuit (98) being adapted to limit the value of the intensity of the current flowing in said output plug ( 26). 7. Display unit (10) according to claim 5, characterized in that each electrical protection member (70) comprises a voltage comparator (74) with two inputs, a first bipolar transistor (80) and a second bipolar transistor (82). ). 8. Display stand (10) according to any one of the preceding claims, characterized in that the presentation structure (14) comprises several shelves (15A) for presenting the products, and in that the lighting means (18) comprise at least two lighting members (20) and a number of power supply input plugs (22) equal to the number of shelves (15A) of the presentation structure (14), each shelf (15A) being intended to be illuminated by a lighting member (20) connected to an associated power input plug (22). 9. Display unit (10) according to any one of the preceding claims, characterized in that the ratio between the electrical power delivered on each output plug (26) and the electrical power outputted from the voltage source (24) is limited by a maximum value of between 0.09 and 0.25, preferably substantially equal to 0.15.