NO123355B - - Google Patents

Description

Contact device for electrical

timers or similar.

The present invention relates to a contact device for electric time switches or the like with simultaneous operation of at least two poles and other outputs in accordance with the introduction to patent claim 1 below.

In the case of known electric time switches of this type, either a mechanical or electric clockwork has been used to drive the contact device. In order to achieve a sufficiently high contact pressure, due to the large displacement forces required, it has been necessary to use relatively powerful movements. The disadvantages of this are still present.

Such a time switch becomes expensive to manufacture and becomes towering and bulky, which makes it difficult to use when there is only limited space available.

The purpose of the present invention is to provide a contact device for electric switches with which it becomes possible to achieve high contact pressures even with very small displacement forces, which of course also entails the advantage that the time switch can be made small and light. The purpose is achieved by the time switch having the characteristics specified in the patent claims.

The invention will be described in more detail below

reference to the drawing, which shows an embodiment of the invention. Fig. 1 is a perspective view of a time switch with a contact device according to the invention. Fig. 2 shows the contact device in the time switch in fig. 1 in

closed position.

Fig. 3 shows the same contact device in the open position.

In fig. 1, as an example of an application of the invention, a time switch 1 is shown. This contains a contact device according to the invention and is fed with current from an ordinary plug socket via a plug 2. With the help of the contact device, current can be supplied in the course of an optional time consumer through a wire 3- The times for connecting and disconnecting the current to the consumer are set using the steering wheel 4» 5 °g 6 provided with scales. With the help of an electric motor, these steering wheels in the embodiment shown are driven at a speed of one revolution per hour, but other speeds can of course also be selected if this is desired. Maneuvering of the contact device then takes place in accordance with the set values by means of a maneuvering slide 7>, one end of which is visible in fig. 1, and which is provided with a pin which is acted upon in different directions by cams on the steering wheels 5 and 6. The slide 7 can also be acted upon manually at any time without this affecting the setting made, which allows a connection and a disconnection for each turn of the wheels 4> 5 °S 6.

Fig. 2 and 3 show the contact device according to the invention in the closed and open positions, respectively. The contact device includes two contact arms 8 and 9 which are pivotably connected with each bracket 10, resp. 11, attached to a frame 12. At the end facing away from the respective bracket, each contact arm has 8, resp. 9»©n contact pin 13 as in the one in fig. The closed position shown in 2 adjoins a fixed one

contact pin 14 on a bracket 15, resp. 16. Wires 17 are connected to the brackets 10, 11, 15 and 16. In the contact device's "open position" shown in fig. 3, the contact arms 8 and 9 rest against supports 18 and 19 respectively (fig. 2).

A pair of leaf springs 20 and 21 are attached with one end to each of the contact arms 8 and 9 - The other end of each leaf spring 20, resp. 21, is connected to the free end of an arm of an angle-weight rod 22, resp. 23, to the influence of the contact arm 8, resp. 9-The angle weight rod 22, resp. 23 is stored on the bracket 10, resp. 11,

and the free end of its other arm is provided with a pin which projects into a hole in the maneuvering slide 7*

The operation of the device is as follows: In fig. 2, the contact device is shown with the contacts closed. When the contact is to be broken and the contact device is brought to the open position in fig. 3> the maneuvering slide 7 is moved in an upward direction from the position in fig. 2. The angle weight rod 22 will then turn clockwise about its storage point 24 - When the angle weight rod 22 has swung so far that the contact point 25 of the spring 20 against the angle weight rod passes the connection line between the storage point 26 for the contact arm 8 on the bracket 10

and the contact surface between the contact pins 13 and 14, the contact arm 8 will switch to the position in fig. 3- Thereby, the direction of the force with which the spring 20 acts on the angle weight rod 22 at the point 25> is changed in such a way that this force gets a greater torque about the point 24 in a clockwise direction. At the same time, the contact arm 9 switches over from the position in fig. 2 to the position in fig. 3> whereby the force with which the spring 21 acts on the angle weight rod 23 changes direction in a corresponding manner, so that the torque on the angle weight rod 23 in the anti-clockwise direction decreases.

As can be seen from the above, the angle weight rod 22 acts on the maneuvering slide 7 with a force which is directed upwards in fig.

2. The angle weight rod 23 simultaneously affects the maneuvering slide 7 with a force in the opposite direction. This means that the two forces in the maneuvering slide 7 counteract each other, and that the resulting force becomes small. When the slide 7 is displaced from the position in fig. 2 to the position in fig. 3", the force from the angle weight rod 23 is initially greater than the force from the angle weight rod 22, so the maneuvering slide 7 is pressed towards the position in fig. 2. When the contact arms 8 and 9 switch over, however, the force from the angle weight rod 22 will increase and the force from the angle weight rod 23 will decrease, which causes the resulting force of the maneuvering slide 7 to change direction, so that the slide quickly moves to the position in fig. 3-

When the maneuvering slide 7 is displaced from the position in fig. 3 to the position in fig. 2, the process described above takes place in the opposite direction. The maneuvering slide is therefore loaded with a relatively small force, and the displacement forces for its adjustment can therefore be small, but still the maneuvering slide has very specific end-

positions, and there is no significant risk that it will be changed unintentionally. Furthermore, the contact pressures can be kept sufficiently

sufficient height to provide satisfactory contact.

The invention is of course not limited to the

form of relationship that is described above and shown in the drawing, as change-

changes and modifications are possible within the framework of the inventive idea and the patent claims below.

Claims (4)

1. Contact device for electrical switches, especially time- switches, with simultaneous operation of at least two poles, each provided with a pivotable spring-loaded contact arm that cooperates with a fixed counter contact, characterized in that the contact arms (8, 9) are arranged in pairs and are operated using a pair of weight rods (22, 23) which are connected together for joint movement and arranged so that each of them is constantly absorbing the effect of a reaction moment in the same direction from the respective contact arm (8, 9) spring (20, 21) and these moments act in the direction of their extreme position of the maneuvering mechanism (22, 23), and that the weight rods during rotation in one direction or the other force the respective springs (20, 21) to pass a dead center and switch the contact arms (8, 9) to the opposite coupling position, and that below , depending on the connection direction, the reaction moment on one barbell (e.g. 22) increases and the reaction moment on the other (e.g. 23) simultaneously decreases or vice versa, so the reaction from the two springs (20, 21) will dominate in each y position and keep the mechanism stable in this. 2. Contact device as specified in claim 1, characterized in that the contact arms (8, 9) with associated springs (20, 21.) and counter contacts (14) are arranged largely rotationally symmetrical, and that the weight rods (22, 23) are designed as angular weight rods and interconnected for rotation in opposite directions. 3. Contact device as stated in claim 1 or 2, characterized in that the spring that affects each contact arm (8, 9) is made up of a leaf spring (20, 21) whose one end is attached to the contact arm (8, 9), °6 the other end of which is connected to one arm of the maneuvering weight rod (22, 23), while its other arm is connected to a maneuvering slide (7) which connects the two maneuvering weight rods in the pair for joint movement. 4. Contact device as stated in claim 1, 2 or 3" characterized in that one pole is closed and the other is open in the respective positions where the associated reaction moment dominates.