IT202300007161A1 - Polymer matrix electromechanical actuator - Google Patents

Description

?Polymer matrix electromechanical actuator?

The present invention relates to an electromechanical actuator made of polymer matrix composite material, which can be used in electrical and electronic devices such as electromechanical relays and thermal switches.

A relay is a switch controlled by an electrical circuit, featuring a set of input terminals and a set of output terminals.

The relay usually switches two or more output terminals (8,9,10) when an appropriate voltage is applied to the input terminals (6,7), or when an appropriate electric current flows in the input terminals (6,7).

The relay is used when there is a need to control a high power or high voltage circuit through a low power circuit, especially in cases where galvanic isolation between the two circuits is also required. Among the various types of relays, there are electromechanical relays, in which the output contacts (8,9,10) are switched through the movement of a mobile contact (4) inside the relay, using an electromagnet (1) as an electromechanical actuator, as shown in FIG.1 and FIG.2.

Thermal switches, on the other hand, are electrical devices capable of interrupting an electrical circuit in the event that the intensity of the electric current in a conductor exceeds a pre-set value, and therefore act as overcurrent protection devices when installed in series with the circuit to be protected (14).

In this case the actuator that switches the output terminal (13) usually consists of a thermal circuit breaker (11), characterised by a bimetallic plate that deforms and flexes when a pre-set intensity of electric current passes through it, as shown in FIG.3 and FIG.4.

The bimetallic sheet is usually made by coupling, such as welding, gluing or stapling, two metal strips having a different coefficient of linear thermal expansion.

This allows the bimetallic strip to deform and flex when heated by the passage of a certain intensity of electric current, which heats the strip due to the well-known "Joule" effect.

So, in the case of electromechanical relays, the actuator, i.e. the component that converts the incoming electrical energy into mechanical work in order to switch the output terminals, is made by an electromagnet.

In the case of thermal switches, however, the actuator, i.e. the component that converts the incoming electrical energy into mechanical work in order to switch the output terminal, is usually made of a bimetallic sheet. In the first case, the electromagnet has significant disadvantages such as:

- High cost of the electromagnet (1) and moving parts (2).

- Large size of the electromagnet coil (1), usually made up of numerous copper wire windings, which cannot be miniaturised.

- Difficulty in controlling the electromagnet by the intensity of the current present in a conductor, since the electromagnet is usually controlled by the voltage applied to its ends (6,7).

- Little versatility of the electromagnet which cannot be controlled in both direct and alternating voltage.

The above disadvantages make electromechanical relays unsuitable for electrical or electronic applications where a switching circuit sensitive to the input current is desired, such as in self-resetting fuses, selection circuits or current-controlled bypass circuits.

In the second case, however, the bimetallic sheet has significant disadvantages such as:

- High value of current intensity required to sufficiently bend the bimetallic strip.

- Insufficient deformation of the bimetallic strip for low current intensity values.

The above disadvantages make bimetallic strip thermal switches unsuitable for overcurrent protection of low power circuits.

There is a need to improve the current electromechanical actuators used in electrical and electronic components such as relays and thermal switches with components that are more sensitive to low power, usable in both direct current and alternating current, low cost and above all compact.

The purpose of the present invention is to create an electrical component that can perform the functions of an electromechanical actuator in electromechanical relays and the functions of a thermal circuit breaker in thermal switches, fulfilling these needs in a simple and economical manner.

This is accomplished through an electromechanical actuator made from a sheet of polymeric material (16), which has the ability to thermally deform when heated.

Thermal deformation is induced by the heat generated by the "Joule" effect from a metal conductor (15) carrying an electric current, suitably immersed in the polymer matrix (16), as shown in FIG.5 and FIG.6.

In the case of the thermal circuit breaker, all other boundary conditions being equal, as a first approximation, the amount of deflection of the bimetallic plate is proportional to the difference between the two linear thermal expansion coefficients of the two coupled metal plates.

Polymers generally have a higher coefficient of linear thermal expansion than metals, making these materials more suitable for the above uses.

The polymers used as polymer matrix can be thermoplastic or thermosetting.

The relatively high value of the linear thermal expansion coefficient of the polymer, combined with its low thermal conductivity, makes it possible to obtain a significant thermal gradient transverse to the section of the foil, when heated on one side only, due to the heating effect of a conductor crossed by a certain intensity of electric current.

As a consequence, the polymer matrix sheet tends to bend even in the absence of a second coupled material, as instead happens in the case of the bimetallic sheet.

To increase the sensitivity of the component, it is also possible to insert fibres (17) embedded in the polymer matrix, arranged on the side opposite to the conductor, so as to increase the degree of bending of the composite sheet even with a lower or total absence of thermal gradient, as shown in FIG.7 and FIG.8.

As a non-limiting application example, one can consider the insertion of longitudinal glass, aramid or carbon fibres into the polymer matrix (16) which, in addition to providing an easily realisable and low-cost solution, would offer notable functional advantages since, all other conditions being equal, they would increase the degree of flexure of the composite sheet and would guarantee its deformation even when thermal equilibrium is reached.

Similar to what happens with bimetallic sheets, it is possible to size the polymer matrix electromechanical actuator by coupling a second polymer with a lower thermal expansion constant to the polymer matrix.

The shape and geometry of the blade can also vary depending on the specific need.

This makes the polymer matrix electromechanical actuator a versatile, simple and low-cost component. As a non-limiting application example, the polymer matrix can be made from a bar of thermoplastic polymer such as polytetrafluoroethylene PTFE, which has a high thermal resistance and a high coefficient of linear thermal expansion. The conductor embedded in one side of the matrix can be made of copper wire of appropriate section and length and on the side opposite the conductor, glass fibres arranged longitudinally could be inserted.

This electromechanical actuator (18) can replace the electromagnet present inside the electromagnetic relays, as shown in FIG.9 and FIG.10.

The internal electrical conductor can also be connected to a terminal external to the matrix (27), so as to then act as a moving contact to connect and disconnect to an electrical terminal of an external circuit, as occurs with the bimetallic strip in thermal switches, as shown in FIG.11 and FIG.12.

This electromechanical actuator (28) can replace the bimetallic plate inside the thermal switches, as shown in FIG.13 and FIG.14.

DESCRIPTION OF THE FIGURES

Fig.1: Illustration representing the operating principle of an electromechanical relay, when the electromagnet (1) is not in the excited state.

Fig.2: Illustration representing the operating principle of an electromechanical relay, when the electromagnet (1) is in the excited state.

Fig.3: Circuit diagram representing the operating principle of a thermal switch, when the bimetallic strip (11) is not sufficiently deformed.

Fig.4: Circuit diagram representing the operating principle of a thermal switch, when the bimetallic strip (11) is sufficiently deformed.

Fig.5: Illustration representing the polymer matrix electromechanical actuator with matrix (16) and conductor (15) not assembled.

Fig.6: Illustration representing the polymer matrix electromechanical actuator with matrix (16) and conductor (15) assembled.

Fig.7: Illustration representing the polymer matrix electromechanical actuator with matrix (16), conductor (15) and fibres (17) unassembled.

Fig.8: Illustration representing the polymer matrix electromechanical actuator with matrix (16), conductor (15) and fibres (17) assembled.

Fig.9: Illustration representing the operating principle of an electromechanical relay with a polymer matrix electromechanical actuator (18), when the actuator is not deformed.

Fig.10: Illustration representing the operating principle of an electromechanical relay with a polymer matrix electromechanical actuator (18), when the actuator is deformed.

Fig.11: Illustration representing the polymer matrix electromechanical actuator with matrix (16) and electrical conductor (15) connected to the external contact (27) not assembled.

Fig.12: Illustration representing the polymer matrix electromechanical actuator with matrix (16) and electrical conductor (15) connected to the external contact (27) assembled.

Fig.13: Circuit diagram representing the operating principle of a thermal switch with a polymer matrix electromechanical actuator (28), when the actuator is not sufficiently deformed.

Fig.14: Circuit diagram representing the operating principle of a thermal switch with a polymer matrix electromechanical actuator (28), when the actuator is sufficiently deformed.

REFERENCE NUMBERS

1:electromagnet; 2:anchor; 3:fixed contact; 4:moving contact; 5:fixed contact; 6-7:input terminals; 8-10:output terminals; 11:bimetallic strip; 12:moving contact; 13:fixed contact; 14:electrical circuit; 15:electrical conductor; 16:polymer matrix; 17:fibers; 18:polymer matrix electromechanical actuator; 19:fixed contact; 20:moving contact; 21:fixed contact; 22-23:input terminals; 24-26:output terminals; 27:external contact; 28:polymer matrix electromechanical actuator; 29:moving contact.

Claims (5)

1. Polymer matrix electromechanical actuator comprising: - at least one solid body of polymeric material (16); - at least one electrical conductor (15) arranged internally to the solid body (16), partially or totally, or even adjacent to the solid body (16) characterised by the fact that it deforms due to thermal deformation following heating of the conductor (15) when this is crossed by a certain intensity of electric current. 2. Polymer matrix electromechanical actuator as per claim 1 which also comprises: - One or more fibres (17) of material different from the matrix (16) arranged internally to the polymer matrix (16) characterised by the fact that the fibres (17), having a thermal expansion coefficient different from that of the polymer matrix (16), increase the amount of deformation of the matrix (16) when an electric current passes through the conductor (15). 3. Polymer matrix electromechanical actuator as per claim 1 which also comprises: - One or more fibres (17) of material different from the matrix (16) arranged internally to the polymer matrix (16) characterised by the fact that the fibres (17), having a thermal expansion coefficient different from the polymer matrix (16) ensure a bending of the matrix (16) when heated, even when thermal equilibrium is reached. 4. Polymer matrix electromechanical actuator as per claim 1 which also comprises: - A second solid body adjacent to the polymer matrix (16) also made of polymeric material, with a different linear thermal expansion coefficient than the matrix (16) characterized by the fact that the adjacent body, having a linear thermal expansion coefficient lower than the polymer matrix (16) guarantees a bending of the polymer matrix even when thermal equilibrium is reached. 5. Polymer matrix electromechanical actuator as per claim 1 which also comprises: - A conductive terminal (27) external to the polymer matrix (16) connected to the internal conductor (15) characterised in that the external terminal (27) can be used as a moving contact (29) to connect or disconnect to a contact of an external circuit (13), similar to what is already performed by the thermal circuit breaker (11).