DE10104438A1 - Safety circuit-breaker for water heater, has anchor bolt actuated by electromagnetic coil or pressure pin - Google Patents

Abstract

A slider (10) is operated via an anchor bolt (12) when the bolt is actuated by an electromagnetic coil, and/or the bolt is moved by a pressure pin (17) of a pressure sensor. The anchor bolt and pressure pin may be made as one part, and/or may be held in position by a spring which produces a spring force that, together with frictional forces, defines the trigger force.

Description

The invention relates to a safety switch Water heater with physical quantities to be protected Device-influenced switchgear.

With the pressure-sensitive switch-off function, the pressure is Membrane converted into a force, whereas the electrical operated switching function, first a sensor system detects a value, which is used to switch off. After the sensors, whether electrical driven or operated by pressure, the switch has opened, is one Reactivation only via an additional actuator which by Must be operated manually, can be switched on again.

DE 195 25 313 A1 describes a multi-pole safety switch known. This opens a drivable by a sensor element Trigger link the contact set. The trigger link is one Release spring loaded axially and has a release curve. A radial Slidable locking pin prevents the switching sleeve from opening Switch-on position opens the contact set. By design the switching spring and thus the switching force is determined when the Contact set opens. Serve as sensor elements, for example Water pressure sensors, steam pressure sensors, expansion sensors or magnetic drives.  

An electrical, temperature or pressure operated Snap switch is known from DE-PS 11 65 723. Here stops Contact carrier several movable contacts that are biased Leaf springs when the dead center position of a sensor tappet is exceeded are suddenly switchable to the other position. The elastic shape change in the snap-action derailleur is or organs sensitive to pressure. When you reach one predetermined value, there is a sudden change in the Switching elements in their opposite position. With help of a The push button is turned into a guide plate by hand shifted in the opposite direction.

A switch, especially a temperature controlled one Safety switch for electrically heated water devices is from DE- AS 2425485 known. The switching elements are by a actuatable locking device held in a biased position. The switching process is carried out by a movable control slide reached. The spring through which a force on the spool is not axially to the direction of movement Control spool arranged. By tilting the spring a force component is provided that the spool in expresses a precisely defined stable starting position and thereby more or less large clearance in the slide guide. A U shaped bracket is coupled to the locking element so that a free Limits the movement of the control spool. A Expansion device, which is operated via pressure, can the bracket move the locking element into the release position.

A force acts on each of these rear derailleurs via a sensor system is generated on the trip unit of the contacts.

The invention specified in claim 1 is the problem based on the sensory detection of various physical quantities and transfer to the safety switch so that the contacts can be opened safely.  

This problem is caused by those listed in claim 1 Features solved.

The advantages achieved with the invention are in particular that different physical quantities are recorded, these in Safety switches can be converted into mechanical forces and according to a respectively assigned limit value to a safe one and defined opening of the contacts. It is with the present invention an independent function triggering the different forces possible. With simultaneous action of the forces they support and complement each other. On the one hand will be at anchor Forces induced when there is a voltage change in the coil. This is triggered by an upstream control unit, which with any signals, preferably temperature signals becomes. The pressure forces to be monitored are, however, directly in the Membrane sensed and simultaneously in the membrane in a Force converted. The membrane therefore fulfills the functions of Sensor, the control unit and the force-generating unit.

An advantageous embodiment of the invention is the arrangement of the force-generating or force-transmitting components in one axis.

It is also advantageous if the force effects of both elements in point in the same direction and the force-transmitting components can work separately.

An advantageous embodiment of the invention results from the following description. The drawing shows:

Fig. 1 shows a 3-pole circuit breaker in a sectional view,

Fig. 2 the switch with housing, coil and connecting parts, and

Fig. 3 shows the pressure-sensitive area in section.

A safety switch 1 consists of a multi-part housing 2 .

Area the pressure plate 3 is arranged for receiving the electrical contacts 4 and the electrical terminals, not shown. A positioning dome 6 is formed on the pressure plate 3 on the right and left for receiving and positioning compression springs 5 . The contacts 4 attached to the pressure plate 3 are not movable and locked in place. With the help of four screws, not shown, the pressure plate 3 is fastened to the housing 2 through bores, not shown.

An insulating and holding plate 7 is arranged above the pressure plate 3 . The contacts 9 are arranged in this and are elastic via the contact force-generating contact pressure spring 8 . The insulating and holding plate 7 is pressed by a slide 10 into a position in which the contacts 9 contact the contacts 4 . The position is also selected so that the contact pressure springs 8 generate a pressure force sufficient for safe current flow. Furthermore, the compression springs 5 are compressed under tension, so that a further force acts between the insulating and holding plate 7 and the pressure plate 3 . This positioning ensures that there are sufficient contact forces on the electrical contacts 4 , 9 and that the compression springs 5 provide sufficient forces to isolate the insulating and holding plate 7 with the contacts 9 from the pressure plate 3 with the contacts 4 in the event of a malfunction to separate so that no more electrical current flows.

The force effects, generated by the compression springs 5 and 8 between the pressure plate and the insulating and holding plate, result from the forced positioning of the components, which is determined by the slide 10 . The slide 10 is in turn positioned by the bolt end 11 of the armature 12 . The armature 12 is a round bolt which is held in the coil carrier 13 in an axially movable manner. Also attached to the coil carrier 13 is the coil 14 , with which the necessary opening forces are generated in the anchor bolt 12 . For operation "trouble-free", the anchor bolt 12 is locked in its axial position by a return spring 15 . In the "malfunction" operating state, when the bolt end 11 forcibly releases the slide 10 , a force is induced in the anchor bolt 12 which is greater than the restoring forces of the restoring spring 15 and the total frictional forces of the system. In this case, the anchor bolt 12 is suddenly struck to the right in the counter bearing 16 . The slider 10 is also suddenly pushed up by the force of the compression springs 5 and 8 on the insulating and holding plate 7 . Now the insulating and holding plate 7 is free from the slide 10 and is lifted so far by the forces of the compression springs 5 that the contacts 4 , 9 are open.

The pressure-sensitive side of the switch 1 has a similar behavior. A pressure pin 17 is arranged in the same axial direction as the anchor bolt 12 . It is pressed against the bolt end 11 of the anchor bolt 12 by the membrane 18 . So that the membrane 18 cannot be damaged by excessive movement of the pressure pin 17 , so that a definite final positioning of the pressure pin 17 with respect to the membrane 18 is ensured, it has a pin edge 20 which cannot be pressed beyond the pin bearing 19 . The compressive forces on the membrane 18 occur in the pressure chamber 21 , which has an expansion in the area of the membrane 18 . In this pressure chamber 21 , the membrane 18 can also perform the necessary axial movement. The pressure of a liquid or a gas reaches the pressure chamber 21 through the pressure channel 22 . The connection pressure channel 23 is located in the upper area of the pressure channel 22 . The pressure channel 22 , the connection pressure channel 23 and the pressure chamber 21 are formed by the connection flange 24 . In the sealing area of the membrane 18 , the connecting flange 24 has an undercut 25 . The undercut 25 serves for secure fixing and for sealing the connecting flange 24 to the housing 2 . It is advantageous to fasten the connecting flange 24 to the housing 2 by means of two screws 31 which engage in the pin bearing 19 . In the sealing zone 26 , the tensile and compressive forces arising in the membrane are absorbed and the sealing effect is generated at the same time.

In the "malfunction", when an excessive deviation of the pressure value from the target value occurs, the membrane 18 transmits an axial force (release force) to the pressure pin 17 which is greater than the sum of the frictional forces in the mechanical release system (in particular between slide 10 and anchor bolt 12 ) and the spring forces of the return spring 15 and the compression spring 27 . In this functional case, the pressure pin 17 is moved in the axial direction and in the direction of the anchor bolt 12 . With the compression spring 27 , the return spring 15 and the forces generated by friction, a defined counterforce to the membrane force is generated, which defines the triggering force. At the end of the pressure pin 17 there is a further pin edge 28 , which likewise limits the axial movement of the pressure pin 17 . Furthermore, a larger contact surface of the membrane 18 on the pressure pin 17 and a shape adaptation of the pressure pin 17 to the membrane 18 is achieved by the pin edge 28 .

In order to achieve a long service life of the component, it is furthermore expedient if the pin edge 28 in the contact area with the membrane 18 is as smooth and burr-free as possible so that it does not damage the membrane 18 . Furthermore, the pressure pin 17 is guided by a pin guide 29 so that it cannot tilt. If the "fault" caused by a pressure deviation now occurs, the pressure pin 17 presses the bolt end 11 of the anchor bolt 12 as far as to the side that the slide 10 is also exposed and thus triggers a sudden opening of the electrical contacts 4 , 9 .

A one-piece design of anchor bolt and pressure pin is advantageous. This means the number of parts and bearing points in the system reduced (not shown).

If a pressure deviation occurs simultaneously with a force acting on the anchor bolt 12 (triggered by a sensor system), the forces of the pressure and the anchor bolt forces occurring in the same direction complement each other, so that the switch-off is also ensured in this case.

An automatic restart of the system is not possible. To restart, ie to close the electrical contacts 4 , 9 , it is necessary to push the slide 10 back into its desired position. This is carried out with the aid of a reset pin, not shown, which acts on the rocker 30 . By overcoming the spring forces of the contact pressure spring 8 and the pressure spring 5 , the system is brought back into the "closed" position.

Claims (14)

1. Safety switch of a water heater with switching mechanism influenced by physical quantities in the device to be protected, characterized in that a slide ( 10 ) is actuated by an anchor bolt ( 12 ) when the anchor bolt ( 12 ) is driven by an electromagnetic coil ( 14 ) and / or the anchor bolt ( 12 ) is moved by a pressure pin ( 17 ) of a pressure sensor. 2. Safety switch according to claim 1, characterized in that the anchor bolt ( 12 ) and the pressure pin ( 17 ) are designed together as one part. 3. Safety switch according to claim 1, characterized in that the central axes of the pressure pin ( 17 ) and the anchor bolt ( 12 ) are in line. 4. Safety switch according to claim 1, characterized in that the central axes of the pressure pin ( 17 ) and the anchor bolt ( 12 ) are offset from one another. 5. Safety switch according to one of the preceding claims, characterized in that the pressure pin ( 17 ) and the anchor bolt ( 12 ) are held in position by at least one spring and that this spring generates a defined spring force which, together with the frictional forces, defines the triggering force , 6. Safety switch according to one of the preceding claims, characterized in that the electrical contacts ( 4 , 9 ) are opened in the event of a trip. 7. Safety switch according to one of the preceding claims, characterized in that the electrical contacts ( 4 , 9 ) are closed in the event of a trip. 8. Safety switch according to one of the preceding claims, characterized in that the contacts on the insulating and holding plate ( 7 ) are reset via a pin acting on a rocker ( 30 ). 9. Safety switch according to one of the preceding claims, characterized in that a pressure chamber ( 21 ) above the membrane ( 18 ) is formed and this with a pressure channel ( 22 ) and a connection pressure channel ( 23 ) can be connected to the pressure system to be monitored. 10. Safety switch according to one of the preceding claims, characterized in that the housing ( 2 ) has a connecting flange ( 24 ) with sealing surfaces. 11. Safety switch according to one of the preceding claims, characterized in that the connecting flange ( 24 ) is fastened to the housing ( 2 ) with screws and a flange plate. 12. Safety switch according to one of the preceding claims, characterized in that the connecting pressure channel ( 23 ) is integrated as a single part with a sealant in a pressure-tight manner in the connecting flange ( 24 ). 13. Safety switch according to one of the preceding claims, characterized in that the connecting flange ( 24 ) points upwards. 14. Safety switch according to one of the preceding claims, characterized in that the connecting flange ( 24 ) is arranged horizontally.