DE29823117U1 - Electrical device for potentially explosive areas - Google Patents

Description

GR 98 G 4466 EN

Description

Electrical equipment for potentially explosive atmospheres

The invention relates to an electrical device for potentially explosive areas according to the preamble of claim 1.

In order to be approved as equipment for use in potentially explosive atmospheres, electrical devices must meet certain requirements, which are laid down, for example, in standards EN 50014 and EN 50020. In particular, devices are divided into different temperature classes according to the permissible surface temperature: For temperature class T4, the maximum surface temperature is 135 ⁰ C, for temperature class T5 100 ⁰ C and for temperature class T6 85 ⁰ C. The surface temperature limit must be observed, for example, when using intrinsically safe field buses, in which several field devices are remotely supplied with the required operating energy via the same two-wire cable. Suitable measures must be taken to ensure that the permissible maximum value of the surface temperature is not exceeded even in the event of a fault if the entire operating energy provided by the field bus is only consumed by one field device. Depending on the design, the field bus power supply can supply up to 4.2 W. Suitable measures to protect against overheating include, for example, current and/or voltage limitation using ohmic resistors or Zener diodes. However, these measures disadvantageously reduce the operating energy provided for the individual field devices because they reduce the efficiency of the energy transfer.

The invention is based on the object of creating an electrical device for potentially explosive areas, in which it can be ensured with little effort that

GR 98 G 4466 EN

a permissible surface temperature is not exceeded.

To achieve this object, the new electrical device of the type mentioned at the outset has the features specified in the characterizing part of claim 1. Advantageous developments of the invention are described in the subclaims.

The invention has the advantage that effective energy utilization is guaranteed, since the thermal fuse has no significant influence on the energy transfer during normal operation. In the event of a fault, however, when the temperature exceeds a defined threshold, the thermal fuse (overtemperature fuse) reliably interrupts the supply of electrical energy. If required, the thermal fuse can easily be designed redundantly. Potting the parts of the electrical circuit that can generate increased thermal output in the event of a fault prevents local heating of components, a so-called hotspot, from immediately causing an increase in the surface temperature above the permissible limit. Before the hotspot can spread across the entire potting compound and cause the surface temperature to rise too high, the thermal fuse responds and interrupts the further supply of electrical energy.

A good thermal coupling between the possibly heat-generating circuit parts and the thermal fuse is advantageously achieved if they are embedded together in the potting compound.

In order to reliably ensure that the surface temperature is always lower than the temperature detected by the thermal fuse, the thermal fuse can be embedded in the casting compound in such a way that it advantageously reduces the temperature in the heat transfer area between the heat

GR 98 G 4466 EN

generating circuit parts and the surface of the potting compound.

With moderately heat-conducting casting compound, a uniform temperature profile on the surface of the casting body is advantageously achieved if a highly heat-conducting body is embedded in the casting compound, which essentially surrounds the heat-generating circuit parts.

The invention is particularly advantageously applicable to field devices for use in potentially explosive atmospheres, which transmit data via a fieldbus and are remotely powered via the same fieldbus.

The invention as well as its embodiments and advantages are explained in more detail below with reference to the drawings in which embodiments of the invention are shown.

Show it:

Figure 1 shows the basic structure of an electronic device,

Figure 2 shows an example of an electrical connection of a thermal fuse in a field device with fieldbus connection,
Figure 3 shows a line termination as an electrical device with thermal fuse in the potting and

Figure 4 an electrical device with uniform surface temperature at the casting.

Figure 1 shows a sectional view of the internal structure of an electronic device with a circuit board 1, which is equipped with two possibly heat-generating components 2 and 3 and with a thermal fuse 4. The thermal fuse 4 is embedded together with the components 2 and 3 in a potting compound 5. It is arranged in such a way that it reduces the temperature in the heat transfer area between the components 2 and 3 and a surface 6 of the potting compound.

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GR 98 G 4466 EN

detected. Two connections 7 and 8 of the thermal fuse 4 lead to the circuit board 1 and are soldered there. The supply current of the components 2 and 3 is conducted via these connections 7 and 8, so that when the thermal fuse 4 is triggered, the current flow and thus the supply of electrical energy to the components 2 and 3 can be interrupted in a simple manner, as if by a thermal switch. An unacceptable increase in the surface temperature on the underside of the potting 5 is prevented by copper layers in the circuit board 1, which evenly distribute the heat in the potting.

In the embodiment shown, the parts of the electrical circuit that can generate increased thermal power in the event of a fault are spatially grouped together at one point on the circuit board 1. The thermal fuse 4 is arranged above the circuit parts in such a way that it responds immediately to an increase in temperature. If circuit parts that represent a potential heat source cannot be grouped together for special reasons and have to be arranged in a distributed manner in the electrical device, they can be encapsulated separately and each provided with a thermal fuse.

Figure 2 shows the electrical connection of a thermal fuse 9 in a field device that is supplied with the required operating energy via a field bus. On the field bus, data and electrical energy are transmitted to the individual field devices via electrical lines 10 and 11, of which only a section is shown here. Two electrical lines 12 and 13 are used to supply an electrical circuit 14 of a field device with the energy required for operation and to carry out the data exchange. The thermal fuse 9 is inserted into the electrical line 12 so that the circuit can be easily interrupted when the thermal fuse 9 is triggered. The thermal fuse 9 and the parts of the electrical circuit

GR 98 G 4466 EN

, which can generate increased thermal power in the event of a fault, are embedded in a potting compound 15, as already described with reference to Figure 1.

The electrical device shown in Figure 3 is a device for terminating a field bus line. Parts already introduced in Figure 2 are provided with the same reference numerals. An electrical circuit that can generate increased thermal power in the event of a fault consists here of an ohmic resistor 16 and a capacitor 17, to which an additional ohmic resistor 18, shown with broken lines, can optionally be connected in parallel.

The electrical device shown in Figure 4 contains a circuit board 19, which is equipped with two possibly heat-generating components 20 and 21. The components 20 and

21 are made of a grid-shaped, good heat-conducting body

22. Furthermore, a thermal fuse 23 is provided, which is embedded together with the components 20 and 21 and with the body 22 in a casting 24 and is arranged in such a way that there is a good thermal coupling to the body 22. The good heat-conducting body 22 advantageously achieves a uniform distribution of the surface temperature of the casting 24.

In areas at risk of explosion, encapsulation of any heat-generating components has the additional advantage that the overall surface temperature is reduced, allowing higher input power. Since voltage limitation is only necessary at the points facing outwards, the circuit complexity is reduced. There are no restrictions on the internal capacitances and inductances that do not have an external effect, and depending on the circuit, better technical data can be achieved, particularly due to a more stable supply voltage. Since smaller distances between potential

GR 98 G 4466 EN

tial-carrying parts are permissible, the geometric dimensions of the circuit can be reduced.

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Claims (5)

1. Electrical device for potentially explosive areas with an electrical circuit ( 2 , 3 , 4 ) to which electrical energy can be supplied via electrical lines, characterized in that at least the parts of the electrical circuit ( 2 , 3 ) which can generate increased thermal power in the event of a fault are embedded in a casting compound ( 5 ) and that a thermal fuse ( 4 ) is provided which is thermally coupled to the casting compound ( 5 ) and interrupts the supply of electrical energy when a temperature threshold is exceeded. 2. Electrical device according to claim 1, characterized in that the thermal fuse ( 4 ) with the heat-generating circuit parts ( 2 , 3 ) is embedded in the casting compound ( 5 ). 3. Electrical device according to claim 1 or 2, characterized in that the thermal fuse ( 4 ) is embedded in the potting compound ( 5 ) in such a way that it detects the temperature in the heat transfer area between the heat-generating circuit parts ( 2 , 3 ) and the surface ( 6 ) of the potting compound ( 5 ). 4. Electrical device according to one of the preceding claims, characterized in that a body ( 22 ) with good heat conduction is embedded in the casting compound ( 24 ), which body essentially surrounds the heat-generating circuit parts ( 20 , 21 ). 5. Electrical device according to one of the preceding claims, characterized in that it is designed as a field device and that the electrical lines ( 12 , 13 ) can be connected to a field bus ( 10 , 11 ).