DE69020618T2 - Function display device for an electromagnetic relay. - Google Patents

Description

The present invention relates generally to a function indicator device for an electromagnetic relay in which a direct current voltage can be applied to a relay winding.

In general, the electromagnetic relay, as shown in Fig. 8, consists of an electromagnet 4 having an L-shaped yoke 3 fixed to one end of an iron core 2 with a primary winding 1 wound around it for energization, an L-shaped movable iron piece supported by the head end of the yoke 3 and provided to be free to swing in accordance with the energization and de-energization of the electromagnet 4, and a contact mechanism (not shown) controlled by the movable iron piece 5.

In this type of electromagnetic relay, a function indicator device is arranged in which a secondary winding 6 for the function display is wound around the iron core 2 of the electromagnet 4 separately from the primary winding 1 and a function display circuit 10, which consists of a current limiting resistor 8 and a light-emitting diode 9, is connected parallel to the secondary winding 6 to the winding terminals 7a, 7b of the secondary winding 6.

Since the voltage on the secondary winding side is generated by the induction due to the change of the magnetic field induced in the iron core 2, if the alternating voltage is applied to the primary winding 1 to perform the operation, the light-emitting diode 9 of the function display circuit 10 is lit by the voltage on the secondary winding 6 side so as to provide the function display.

However, if a function indicating device similar in structure to the electromagnetic relay for AC operation is used in the electromagnetic relay which applies the DC voltage to the relay winding, the magnetic field generated in the iron core by the excitation in the primary winding becomes constant and the electromotive voltage is not generated in the secondary winding, so that no current flows into the function indicating circuit and the function indication is not performed.

Usually, in the function display device for the DC electromagnetic relay, the function display circuit 10 is connected in parallel with the excitation winding 11 to the winding terminals 12a, 12b of the excitation winding 11, as shown in Fig. 9.

However, in the function display device for the DC electromagnetic relay such as this one, the current flows into the function display circuit 10 even if the operation is stopped due to a break in the Excitation winding 11 is not caused to light up the LED 9 because the function display circuit 10 and the excitation winding 11 are parallel to each other, whereby there is a problem in that correct function display is not performed.

Also, since the excitation voltages are applied to the coil terminals 12a, 12b as they are applied to the function display circuit 10, a function display circuit 10 differing in resistance value must be provided for each of the electromagnetic relays differing in rated value of excitation voltage, resulting in lower productivity with a problem that the light emitting diode 9 does not function properly after applying the high voltages such as surge voltage, etc. to the function display circuit 10 or the like.

Furthermore, EP-A-0308547 discloses an electromagnetic relay in which a function indication circuit comprising a light-emitting diode is connected to the winding of the relay.

According to the present invention, there is provided a function display device for an electromagnetic relay comprising a coil and a function display circuit having a light emitting element connected to the coil;

wherein the winding comprises a primary winding and a secondary winding wound around an iron core so that a series connection of primary winding and secondary winding is provided; and

the function display circuit is connected in parallel to the secondary winding.

According to the structure of the invention described above, the partial voltage corresponding to the impedance ratio between the primary winding and the secondary winding is applied to the function display circuit to perform the display operation.

If the primary winding is broken, the function indicator circuit will not work because current will not flow into the secondary winding either. If the secondary winding is broken, the brightness of the light-emitting element of the function indicator circuit will also change because the voltage applied to the function indicator circuit will change.

According to the structure of the present invention, since the secondary winding can be wound on the inside where the deterioration caused by temperature is likely to be the highest, the secondary winding is also first deteriorated to the point of interruption due to years of use, so as to change the brightness of the light-emitting element of the function display circuit.

Furthermore, an embodiment of the present invention can provide an electrical connection structure of the winding terminal in which large initial stress does not occur and breakage of the welded part, cracking of the winding and breakage of the winding connection terminal do not occur. Therefore, the output wire of the winding wound around a drum of a coil of the core is fixed to a base part of a winding connection terminal protruding from a flange part of the coil so as to effect the electrical connection, and also the free end part of the winding connection terminal is fixed by welding to the winding terminal protruding from the top of a base plate to which the core is fixed, the free end part of the winding connection terminal being elongated and having a curved shape. and whose head end part is attached to the winding terminal by welding.

An embodiment of the present invention will now be described in detail, by way of example, with reference to the accompanying drawings, in which:

Fig. 1 is a circuit diagram of the function display device according to the present invention;

Fig. 2 is a perspective view of an electromagnetic relay equipped with a function display device according to the present invention;

Fig. 3 to Fig. 5 illustrate an embodiment of the structure of the electrical connection of a winding terminal according to the present invention;

Fig. 3 is a perspective view showing the connection state;

Fig. 4 is an enlarged perspective view of the essential parts thereof;

Fig. 5 is an enlarged side view of the essential parts thereof;

Fig. 6 is a perspective view of the completed winding device;

Fig. 7 is an explanatory view showing a method of assembling the winding device;

Fig. 8 is a circuit diagram of the function display device of the conventional electromagnetic relay for AC operation; and Fig. 9 is a circuit diagram of the function indicating device for the conventional DC operation electromagnetic relay.

Before the description of the present invention proceeds, it should be noted that like parts are designated by like reference numerals throughout the accompanying drawings.

Referring now to the figures, Fig. 1 shows a circuit diagram for the function display device according to the invention in accordance with a preferred embodiment of the present invention, wherein the excitation winding has a primary winding 13 and a secondary winding 14 wound around the iron core 2, wherein both the ends of the secondary winding 14 are connected to connecting parts 15a, 15b to provide a series connection of the primary winding 13 and the secondary winding 14 via the connecting part 15b, and the function display circuit 10 is connected in parallel to the connecting parts 15a, 15b.

Fig. 2 shows an electromagnetic relay equipped with a function indicator device corresponding to the circuit structure.

The electromagnet 4 is fixed so that the iron core 2 (not shown) is parallel to the base plate 16 by press-fitting the yoke 3 into the base plate 16. A function display circuit retaining block 17, to which a current limiting resistor 8 and a light-emitting diode 9 are fixed, is fixed to the top of the yoke 3 by means of the hook 18.

The movable iron piece 5 is supported in engagement with the head end of the yoke 3 so that it can swing freely and is also urged in one direction by the coil spring 19 which is away from the pole face of the iron core 2 (not shown). A pair of movable contact pieces 20, 20 having the movable contact are fixed to the movable iron piece 5. The movable contact pieces 20, 20 are connected by wires 22, 22 to the movable contact terminals 21, 21 fixed to the base plate 16. The movable contact of the movable contact pieces 20 and 20 is designed to be positioned between the normally open contact of the stationary terminals 23, 23 fixed to the base plate 16 on the normally open side and the normally closed contact of the stationary terminals 24, 24 on the normally closed side.

The primary winding 13 and the secondary winding 14 are wound around the iron core 2 (not shown) so that the secondary winding 14 is inside. The output wire 13a from one end of the primary winding 13 is connected to the connecting part 15b of the head end of the lead portion 9a of the light-emitting diode 9, and the output wire 13b of the other end is connected to the winding terminal 25b fixed to the base plate 16. Also, the output wire not shown at one end of the secondary winding 14 is connected to the connecting part 15a (not shown) of the head end of the lead portion 8a of the current limiting resistor 8, and the output wire 14b of the other end is connected to the connecting part 15b. Furthermore, the connecting part 15a (not shown) of the head end of the supply line piece 8a is connected to the winding terminal 25a (not shown).

If the DC voltage is applied between the winding terminals 25a, 25b to excite the primary winding 13 and the secondary winding 14 in the electromagnetic relay, the movable iron piece 5 is attracted to the iron core to drive the movable contact parts 20, 20 so that that the normally closed contact is opened and the normally open contact is closed.

At the same time, the partial voltage corresponding to the impedance ratio between the primary winding 13 and the secondary winding 14 is applied to the function display circuit 10 through the connecting parts 15a, 15b. Thus, it is determined that the light-emitting diode 9 emits light and the electromagnetic relay is in the operating state.

Assuming that the primary winding 13 is interrupted and that no current flows into the secondary winding 14, and of course also not into the primary winding 13, the electromagnetic relay is not activated and the LED does not emit any light. Therefore, the function display is carried out in accordance with the activation of the electromagnetic relay.

Even if it is assumed that the secondary winding 14 has been interrupted, the brightness of the LED 9 changes because the voltage applied to the function display circuit 10 changes. Therefore, it can be determined that the secondary winding 14 is defective.

In the present embodiment, since the secondary winding 14 is wound on the inner side closer to the iron core 2 than the primary winding 13, the temperature is higher so that the deterioration occurs sooner. Therefore, due to years of use, the secondary winding 14 is deteriorated first and the impedance of the secondary winding 14 is reduced so that the partial voltage ratio is lowered to reduce the voltage applied to the function display circuit 10 so that the brightness of the light emitting diode 9 decreases. Therefore, the deterioration state of the winding, namely its life, can be predicted so that trouble by burning out or the like of the winding can be prevented, which results in safety.

Even if the electromagnetic relay differs in the rated value of the excitation voltage, the partial voltage of the secondary winding 14, namely, the voltage applied to the function display circuit 10, can be kept constant by adjusting the number of turns or the like of the secondary winding 14. If the function display circuit 10 is further manufactured as a type of components as shown in the function display circuit retaining block 17 shown in Fig. 2, it can be applied even to any electromagnetic relay differing in the excitation voltage, so that the number of components can be reduced and productivity can be improved. Therefore, if the partial voltage of the secondary winding 14 is reduced, the voltage to be applied to the function display circuit 10 can be reduced in contrast to the conventional function display device. Therefore, the high voltage such as a surge voltage or the like to be applied between the coil terminals 25a, 25b is not applied to the light-emitting diode 9, with the result that no trouble may occur. If the coil is in a high-voltage operation, the power consumption of the current limiting resistor 8 can also be reduced.

As is apparent from the above description, according to the arrangement of the present invention, the reliable function indication is performed in accordance with the operation of the electromagnetic relay since the light emitting element does not emit light if the coil is broken.

A self-test to detect abnormalities, such as an interruption of the secondary winding or the like, can be achieved by changing the brightness of the light-emitting element.

Also, the snap action can be performed without a change in the function display circuit by changing or the like the number of turns of the secondary winding with respect to the electromagnetic relay having the different specific excitation voltage values. Therefore, the components for the function display circuit can be standardized to improve the productivity.

Furthermore, since the voltage to be applied to the function display circuit can be reduced by reducing the partial voltage of the secondary winding, it is possible to reduce the number of problems and to lower the power consumption.

In particular, according to the present invention, the life span can be predicted based on the brightness change of the light emitting element, with the result that the troubles caused by the coil burnout or the like can be prevented, resulting in safety.

The structure of the electrical connection of the winding terminal is described below in an exemplary embodiment with reference to Fig. 3 to Fig. 7.

As shown in Fig. 3 to Fig. 7, a winding 14 is wound around the drum part 2 of a coil 30, with flange parts 31, 32 provided at both ends thereof. The output wires 14a, 14a thereof are respectively fixed to the base parts 35a, 35a of a pair of winding connection terminals 35, 35 projecting from the flange part 3 so as to establish the electrical connection therebetween. The free end parts 35b, 35b of the winding connection terminals 35, 35 bent from the base part 35a are respectively connected by welding to the upper end face of the winding terminal 41 (the winding terminal on the inner side is not shown) projecting from the surface of the base plate 4 to establish the electrical connection therebetween. The free end part 35b of the winding connection terminal 35 is bent downward by the height H of the projection part 36 and connected by welding to the upper end face of the winding terminal 41.

In the present embodiment, the free end part 35b of the winding connection terminal 35, which is to protrude from the collar part 3 of the coil 30, is longer than in the conventional embodiment and is bent.

Namely, the free end part 35b of the winding connection terminal 35 has an approximately C-shaped surface, with the projection 36 for welding being provided on the lower surface of the head end part 35c thereof.

Therefore, if the projection 36 for welding is welded to the upper end surface of the coil terminal 41 and is electrically connected therebetween to the head end part 35c bent by the height H of the projection part 36, the spring constant of the free end part 35b is smaller and the spring force of the free end part 35b that must be generated when the joining is carried out by welding becomes smaller than in the conventional example because the essential distance from the base part 35a of the coil connecting terminal 35 of the head end part 35c is larger than in the conventional example. Furthermore, since the linear distance from the welding head end part 35c to the base part 35a is almost similar to that of the conventional example, the bending moment that must be generated when the welding is carried out is smaller than in the conventional example because the free end part 35b as described above, is coupled with the lower spring force.

Accordingly, since the initial stress generated in the free end part 35b of the coil connecting terminal 35 is smaller than in the conventional example, if the projection part 36 of the head end part 35c is connected to the upper end part of the coil terminal 41 by welding, the breakage of the welding part, the cracking of the flange part 32 of the coil 30 and the bending breakage of the coil connecting terminal 35 are not caused. Although a case has been described in the above-described embodiment where the free end part of the coil connecting terminal has an approximately C-shaped surface in the above-described embodiment, the shape is not always limited to the above description, but it will suffice if only the true length of the free end part is large; the shape is not particularly limited to this. Also, the base part of the winding connection terminal does not always have to be bent.

Since the element length from the base part of the winding connection terminal to its head end part is substantially long, it is apparent from the above description according to the structure of the present invention that the flexibility per unit length is relatively smaller and the spring force generated when the welding connection process is performed becomes smaller if the flexibility of the head end part is constant. Furthermore, since the free end part is bent, the straight line distance from the base part to the operating point at which the external force is applied does not become long. The bending moment generated in a case where the welding connection process has been performed is smaller than that of the conventional example, which is due to the smaller spring force of the free end part. related to the above-described issue.

Since the initial stress generated in the free end part of the winding connection terminal is smaller than that of the conventional example, even if the welding connection was performed with the upper end part of the winding terminal with the head end part of the free end part bent by the constant amount, the welding part is hardly broken, resulting in the flange part of the coil and the winding connection terminal not breaking.

Although the foregoing invention has been fully described by way of example with reference to the accompanying drawings, it is to be noted that various changes and modifications will be apparent to those skilled in the art.

Claims (3)

1. A function display device for an electromagnetic relay comprising a winding and a function display circuit having a light emitting element (9) connected to the winding; characterized in that the winding comprises a primary winding (13) and a secondary winding (14) which are wound around an iron core (2) in such a way that a series connection of the primary winding (13) and the secondary winding (14) is effected; and the function display circuit is connected in parallel to the secondary winding. 2. A function display device for an electromagnetic relay according to claim 1, wherein the secondary winding (14) is wound on the inner side of the primary winding (13). 3. A function display device according to claim 1, wherein the lead-out wire (14a) of the winding wound around the drum part of a bobbin (30) of the core (2) is connected to a base part (35a) of a winding connection terminal (35) projecting from a flange part (3) of the bobbin (30), and also the free end part (35b) of the winding connection terminal (35) is fixed by welding to the winding terminal (41) projecting from the upper surface of a base plate to which the core (2) is fixed, and wherein the free end part (35b) of the winding connection terminal (35) is elongated and has a curved shape and the free end part thereof is also fixed by welding to the winding terminal (41).