DE2556289A1 - Pressure operated switch with diaphragm - has adjustable switching differential and trips relay - Google Patents

Abstract

The control element, for the switching system consists of a diaphragm which operates a switch which trips at adjustable thresholds and operates a relay. The switching system may be sensitive to pressure or to other parameters. The switch consists of a change-over switch (3) whose movable contact (4) is operated between two contacts (6,8) by a control element or diaphragm (11). In one position of the switch the relay (1) is energised, and in the other position of the switch the relay is disconnected.

Description

Electrical switching device with switching differential

The invention relates to one of pressure or other physical Size-dependent electrical switching device with adjustable switching differential, in which an actuator, e.g. a diaphragm, actuates a switch arrangement which switches at adjustable limit values and actuates a relay.

Electrical switching devices with adjustable switching differential usually have an electrical snap-action switch, which is a complicated one Structure and has a snap spring, an adjustable setpoint spring and an adjustable Has differential spring. Certain minimum forces are required to operate the snap switch to be available. For many purposes it bothers that the spring characteristics superimpose a non-linear characteristic.

In another known switching device, one of one acts The diaphragm is pressurized and loaded in the opposite direction by a setpoint spring on two microswitches, i.e. snap-action switches with a fixed difference, which are triggered by a Adjustment of their housing are adjustable so that they are approximately at an upper or switch lower pressure limit. The microswitches have normally closed contacts, which are in Row with a relay.

The latching contact of this relay bridges one switch. This results in the required switching differential. Here, too, is Operation of the microswitch the force of the respective snap spring to overcome. This, too, leads to inadequacies in many cases.

Bs are also electrical switching devices with three-point behavior known in which a movable contact element from the actuator continuously is adjustable and can interact with two fixed contacts. When the system is on A first relay is energized via an amplifier at the first fixed contact A second relay is applied to the second fixed contact via an amplifier energized, no relay is energized in any dual position. With such a switch with creeping contact, however, there are none in the border area clear switching states, because already as a result of vibrations in the switching device or vibrations at the monitored size short-term contacts with accordingly brief response of the relay.

The invention is based on the object of a switching device with adjustable switching differential of the type described above, in particular one Pressure switch, to be specified in which the switching system does not interfere with the actuating forces acts back, so that you can work with relatively small forces, and in which shocks and vibrations do not impair the function of the switching system.

This object is achieved according to the invention in that the switch arrangement is formed by a changeover switch, the movable contact element of which is from the actuator continuously freely between two contacts defining the respective switching points is adjustable, the relay is energized in one switching point and in which the relay is de-energized at the other switching point.

This results in a switching device which is a bistable Behavior has, although the changeover switch in the two switching points is creeping Has contact. Because the movable contact element between the two fixed contacts is taken completely freely by the actuator, the switch has in this area has no repercussions on the actuator.

The bistable behavior results from the fact that the relay at the first even brief reaching of one limit value is continuously excited until the other Limit value has been reached.

Here, too, a brief contact is sufficient to make the relay permanent to de-energize until the first-mentioned limit value is reached. liufgrund of so The switching differential setting ensures reliable contact even in the event of vibrations of the device or vibrations of the variable to be monitored. The constructive one Effort is very low because a single switch is sufficient.

In a preferred embodiment, the relay is through the output circuit controlled by a bistable circuit, both of which are each assigned to a switching state Control inputs are each connected to one of the two fixed contacts.

A wide variety of designs are available as bistable circuits into consideration, especially electronic circuits.

Preferably the bistable circuit is a semiconductor, e.g.

Bistable multivibrate having transistors; in its starting circle, E.g. in the collector circuit, the relay winding is switched on. Such flip-flops are customary in the trade.

The bistable behavior can also be achieved by the Relay a self-holding contact that responds to one switching point of the changeover switch and the de-energizing of the relay in the other switching point of the changeover switch by short-circuiting.

A very simple circuit for this results from the fact that the Changeover switch permanently connected to a point between relay and latching contact and the first firm contact with the other side of the self-holding contact and the second fixed contact is connected to the other side of the relay.

To de-energize, the relay is bridged by a short-circuit path. The short circuit is usually harmless because it because of the instant Drop in the latching contact of the relay only lasts for a short time. Where the short circuit current should become too large, you can find a high-ohm resistor in the common supply line and design the relay for a correspondingly low response voltage.

It is particularly advantageous that the relay has a switching contact has, through which a load is fed with AC mains voltage, and that the circuit consisting of a resistor, changeover switch, relay and self-holding contact fed by the same mains voltage via a rectifier and a shunt capacitor is. Despite the desired small currents in the area of the switch can therefore the entire switching device can be operated with mains voltage. An even cheaper one Solution arises if instead of the shunt capacitor a parallel to the relay in Reverse switched diode is provided.

In a preferred embodiment, the movable contact element is at least partially resilient and beyond the position that the movable Contact element assumes when it rests on the first fixed contact, a third is fixed Contact is provided which is electrically connected to the second fixed contact. In this way, the relay is de-energized even if an outside of the Switching differential limit values, the safety limit value is exceeded.

Without giving up the simple structure, there is an additional one Functionality.

The switching differential, especially a large switching differential, can be set in a very simple way if at least one of the fixed contacts adjustable, in particular carried by an adjusting screw.

An embodiment is preferred in which the movable contact element is a one-armed lever that is on the back of the actuator and on the front loaded by a setpoint spring as well as with its free end between the fixed Contacts is arranged, and in which the fixed contact on the rear of the housing is fixed, the Fixed contact on the front attached to a set screw and a pivot point of the lever by means of an adjusting device to be actuated from the front can be displaced approximately perpendicular to the extension of the lever. With the adjusting device can the one limit value of the switching differential, with the adjusting screw the second limit value the switching differential can be set. Both positions are from the front accessible from the lever. The entire rear side can therefore be used for the arrangement of the Actuator, e.g.

a membrane. The expression "front" and '<backside " only relate to accessibility, not to the installation position of the switching device.

In particular, the setpoint spring is supported against rotation secured plate, which is secured against axial displacement by means of the front to be operated screw is axially adjustable. Also the set point spring is therefore easily adjustable.

In a preferred embodiment, the adjusting device has a Screw bolt on, one end of which is in a groove parallel to the bolt axis guided hinge axis is attached, is guided in a housing bore and on the other End carries an adjusting nut, and the lever is slotted over the side The joint axis is pushed and the slot base is pushed against the joint axis by means of a spring pressed.

The lever is particularly advantageous at the free end through a longitudinal slot divided into two parallel longitudinal sections and each longitudinal section a fixed, assigned to a set screw attached contact on the front. These both fixed contacts correspond to the first and third contacts mentioned earlier. If one of the longitudinal sections is already in contact with the associated fixed contact if the lever is further supported, this longitudinal section deforms the second Longitudinal section brought up to the associated fixed contact.

In this connection it is beneficial to use one of the longitudinal sections together with the rest of the lever, it is stiff, while the other longitudinal section is attached b'ederblech is formed.

The stiff longitudinal section is the third fixed contact, the resilient longitudinal section assigned to the first fixed contact.

The switching device described here can be used for numerous Use purposes, namely wherever switching devices with switching differential were used, e.g. as a pressostat, thejostat, travel-dependent Switch etc.

However, it is particularly advantageous to use it as a single membrane designed as an actuator low-pressure pressostat for a maximum pressure from about 4 - 3ù mm S. Because with these small thicknesses it is for a reliable Work of the utmost importance that no essential switch actuation Forces must be overcome. ßin particular advantage.

here it is that while maintaining the Steliweges the Significantly reduce the diaphragm diameter and thus save space. For example could be the diaphragm diameter in low-pressure pressostats, as a result of use of a snap switch was 100 to 125 mm, with otherwise the same conditions below Exploitation of the idea of the invention can be reduced by 15 to 30%. Such Low-pressure pressostats are needed in firing systems, for example, because the To be measured under pressure in the chimney or in the combustion chamber, or in the fan housing a gas burner to monitor the air supply. The pressostat each control means, e.g.

Throttle plates to keep the pressure value within the set difference to keep.

It is also preferred to use it as a gas pressure switch connected to a Gas line is connected and when falling below a limit value of the dynamic Pressure switches off a downstream solenoid valve. In this way it is established that there is a line break and accordingly shuts off the line.

The invention is illustrated below with reference to the drawing Example examples explained in more detail. 1 shows the circuit diagram of the inventive Switching device Illld its use as a pressure switch in a furnace; 2 shows the schematic circuit diagram of a modified switching device; Fig. 3 the use of the switching device as a gas pressure switch; Fig. 4 three switch positions: lungs of the switch; Fi =. 5 shows a section through a pressostat constructed according to the invention and Fi. 0 a top view of the pressostat after removing the cover.

bin relay 1 is in series with its latching contact 2.

din changeover switch 3 has a movable contact element 4, which is permanently is connected to a point 5 between relay 1 and latching contact 2. That Contact element 4 cooperates with a first fixed contact 6, which with a Point 7 on the other side of the self-holding contact is connected, as well as with a second fixed contact 8, the one with a point 9 on the other side of the relay 1 is connected. Furthermore, a third fixed contact 10 can also be present be connected to the second fixed contact 8 and beyond that position of the contact element 4 is arranged, which this fixed when contacting the first Contact 6 occupies. The contact element 4 is continuous from an actuator 11 movable.

A high-resistance resistor 12 is located in the common supply line. Relay 1 is a low voltage relay. The overall arrangement is made up of two Mains AC voltage supplied feed lines 13 and 14 via a diode 15 in a rectified manner Voltage supplied. A reverse-biased diode 16 is parallel to the Relay 1 switched. It ensures that the relay despite the supply of unsmoothed DC does not drop. Instead of this diode 16, a shunt capacitor 16 'can also be used. be used, which smooths the direct current. In special cases there is also the application of diode 16 and shunt capacitor 16 'possible.

In the illustrated embodiment, the actuator 11 is the membrane a pressostat that controls the pressure on the output side of a fan housing 17 monitored by a gas firing system. The gas is fed in via a pipe 18. That Fan 19 is adjustable in speed. A regulator 20 is provided for this purpose.

This is controlled via a work switch 21 of the relay 1.

In the drawing it is assumed that the movable contact element 4 has just reached the fixed contact 6. Relay 1 is energized. The self-holding contact 2 closes. The relay 1 therefore remains energized, even if the contact element 4 again detaches from the fixed contact 6. However, if the contact element 4 is the fixed contact 8, relay 1 is short-circuited. It falls off. This state remains obtained, even if the contact element 4 is released from the fixed contact 8 again. In order to energize the relay 1 again, the contact element 4 must be drawn again Take a stand. This results in the work switch 21 of the relay 1 a switching difference, it goes into one switching position when the actuator 11 reaches the upper limit value and remains in this switch position until the actuator 11 reaches the lower control value. Only then does the switchover to the other take place Switching position which is now retained until the actuator 11 returns to the upper one Limit reached. This results in a very stable two-point control, Here, therefore, a regulation of the air pressure in the fan housing 17.

In the embodiment according to FIG. 3, around 100 are for analog parts increased reference numerals are used. Here the switch 103 is at the two inputs an electronic bistable multivibrator 102, that is to say a flip-flop. In its Output circle relay 101 is switched on. When the moving Contact 104 reaches the fixed contact 106, the bistable multi-vibrator 102 takes the one switching state in which the relay 101 is energized. This state remains obtained even if the movable contact 104 moves away from the fixed contact 106 again solves. If the other fixed contact 108 is reached, the bistable multivibrator picks up 102 the other switching state in which the relay 101 is de-energized. This condition is also retained until the fixed contact 106 is touched again.

In the circuit according to FIG. 3, gas flows over from the distribution network 22 a line 23 to a consumer 24. A pressure regulator 25 is in the line 23 and behind it a solenoid shut-off valve 26 is provided. In between is a pressure switch 27 connected.

This has a circuit structure as in Fig. 1. During normal operation the solenoid valve 26 is switched on via a contact corresponding to the switch 21 Tension laid. However, if the pressure drops so far that the contact element 4 reaches the second fixed contact 8, the relay 1 is de-energized and the solenoid shut-off valve switched off. The same thing happens when the pressure rises above normal and the third fixed contact 10 is contacted. When the line to the consumer breaks and the pressure drops, the solenoid shut-off valve closes. When the pressure regulator 25 fails and the pressure therefore rises excessively, the solenoid shut-off valve closes Likewise. In contrast, the solenoid shut-off valve remains within the permissible pressure range opened because the relay 1 does not respond before one of the fixed contacts 8 or 10 has been touched by the contact element 4. Should the fixed contact 8 only as a result a brief pressure fluctuation, but then through Contacting the fixed contact 6, the specified setpoint can be reached again, the solenoid shut-off valve is switched on again. The same is true when the overpressure ceases and thereby the short circuit established via the fixed contact 10 is canceled will.

Fig. 4 shows the three positions of interest of the switch 3. Position A corresponds to the lower limit value. the position B corresponds to the upper limit and position C corresponds to one beyond safety value lying above the upper limit value.

FIGS. 5 and 6 show a practical exemplary embodiment of a Pressostats according to the invention. & in housing 2S has one on the front Lid 29 and, on the rick side, a base 30 which has a connecting piece 31. This serves both to attach the pressostat and to connect it to the Pressure to be monitored A membrane 32 is clamped between base 30 and housing 28, which is stiffened at the front by a pressure plate 33. On this journey a working pressure chamber 34 is created. A one-armed lever 35 is around a hinge axis 36 pivotable, which can be displaced by means of an adjusting device 37. He is by means of a setpoint spring 38 is pressed against a projection 39 of the pressure plate 33.

The lever 35 consists of a rigid material and is additional between the joint 36 and the adjusting screw 38 by angled flaps 40 stiffened. The free end of the lever 35 is through two longitudinal sections 41 and 42 formed.

For this purpose, the longitudinal section 42 is formed in one piece with the lever 35 and therefore also stiff. The longitudinal section 41, however, is riveted by a Leaf spring formed, so resilient. On an inserted board 43 are except the relay 1 with a contact attachment 44, a fixed contact 45 and two contact arms 46 and 47 each fastened with a set screw 48 and 49, respectively. The set point spring 37 is supported on a secured against rotation plate 50 on a screw 51 can be screwed axially. The screw is in a socket 52 of the housing 28 held against axial displacement. Terminals 53 are provided on the cover, which come to rest on the circuit board 43 by means of spring contacts 54. The cables will guided to the outside through a bushing 55. The diode is also on the circuit board 43 15, the capacitor 16 and the resistor 12 are mounted.

The ends of the hinge axis 36 are in grooves that are parallel to one another 56 guided in the housing. A screw bolt 57 is also welded to it, the is guided through a housing bore and carries an adjusting nut 58 at the other end. In the lobes 40 of the Lever are slots 59, the bottom is pressed against the hinge axis 36 by a helical spring o0. By twisted ones the adjusting nut 58 of the adjusting device 37 can be the joint axis and thus the fulcrum of the lever 35 are shifted.

35 The lift corresponds to the movable contact element 4. If the pressure in the working pressure chamber 34 falls below a predetermined value, the hit Long sections 41 and 42 on the housing-fixed contact 45, which is the second fixed Contact 8 corresponds to.

zein an upper limit is reached, the resilient longitudinal section arrives 41 in contact with the associated adjusting screw 49, which is the first fake contact 6 corresponds. With a further increase in pressure, this first longitudinal section 41 bends until finally the second longitudinal section 42 with the associated adjusting screw 48 comes into contact, which corresponds to the third fixed contact 10.

All adjustable links are from the front, so after removing them of the lid, accessible. The pressure area as a whole is determined by means of the sensor screw 51 set. The lower pressure limit value can be set precisely with the adjusting device 37 will.

With the adjusting screws 48 and 49 the upper pressure limit value or the security pressure can be set precisely.

Claims (18)

Patent Claims 1. From pressure or any other physical quantity dependent L ~ ozelectric switching device with adjustable switching differential, at which actuates an actuator, for example a diaphragm, a switch arrangement which at adjustable limit values and actuates a relay, characterized in that that the switch arrangement is formed by a changeover switch (3,103) whose movable Contact element (4, 104) of the actuator (11, 111) continuously and freely between two contacts (6, 106; 8, 108) defining the respective switching points are adjustable is, whereby the relay (1, 101) is energized in one switching point and in the other Switching point the relay is de-energized. 2. Switching device according to claim 1, characterized in that the peak "'101) is controlled by the output circuit of a bistable circuit /, whose two control inputs each assigned to a switching state each with one of the fixed contacts (in 6, 107) are connected. 3. Switching device according to claim 2, characterized in that the bistable circuit (102) is a semiconductor, e.g. Transistors having bistable multivibrator is in its Output circuit, e.g. in the collector circuit, the relay winding is switched on. 4. Switching device according to claim 1, characterized in that the relay (1) one in the one switching point of the changeover switch (3) responding Has self-holding contact (2) and the de-energization of the relay in the other switching point of the changeover switch is carried out by short-circuiting. 5. Switching device according to claim 4, characterized in that the changeover switch (3) permanently with a point (5) between the relay (1) and the self-holding contact (2) is connected and the first fixed contact (6) with the other side (7) of the Self-holding contact and the second fixed contact (8) with the others Side (9) of the relay is connected. 6. Switching device according to claim 4 or 5, characterized in that that a high-resistance resistor (12) is arranged in the common supply line and the relay (1) is designed for a correspondingly low response voltage. 7. Switching device according to one of claims 4 to 6, characterized in that that the relay (1) has a switching contact (21) via which a consumer with AC voltage is fed, and that the resistor (12), changeover switch (3), Relay and self-holding contact (2) existing circuit from the same mains voltage is fed via a rectifier (15) and a shunt capacitor (16 '). 8. Switching device according to claim 7, characterized in that instead of the shunt capacitor, one connected in parallel to the relay (1) in the reverse direction Diode (16) is provided. 9. Switching device according to one of claims 1 to 8, characterized in that that the movable contact element (4) is at least partially resilient and that beyond the position that the movable contact element when resting on the first Fixed contact (6) occupies, a third fixed contact (10) is provided which is electrically connected to the second fixed contact (8). 10. Switching device according to one of claims 1 to 9, characterized in that that at least one of the fixed contacts (6, 8) is adjustable. 11. Switching device according to claim 10, characterized in that at least one of the fixed contacts is carried by a set screw (48, 49). 12. Switching device according to one of claims 1 to 11, characterized in that that the movable contact element (4) a single arm (35) is that on the back of the actuator (membrane 32) and through on the front a set point spring (37) loaded and with its free end between the fixed Contacts is arranged, and that the fixed contact (45) is fixed to the housing on the back, the fixed contact is attached to a set screw (48, 49) on the front and a pivot point (36) of the lever (35) by means of one from the front actuating adjusting device (37) displaceable approximately perpendicular to the extension of the lever is. 13. Switching device according to claim 12, characterized in that the set point spring (37) is supported on a plate (50) secured against rotation, which are secured against axial displacement from the front actuating screw (51) is axially adjustable. 14. Switching device according to claim 12 or 13, characterized in that that the adjusting device (37) has a screw bolt (57) with a End at a hinge axis (36) guided in grooves (56) parallel to the bolt axis is attached, is guided in a housing bore and at the other end an adjusting nut (58) carries, and that the lever (35) with lateral slots (59) over the hinge axis is pushed and the slot base by means of a spring (60) against the hinge axis is pressed. 15. Switching device according to one of claims 12 to 14, characterized characterized in that the lever (35) at the free end through a longitudinal slot in two parallel longitudinal sections (41, 42) and each longitudinal section a solid, assigned to an adjusting screw (48, 49) attached contact on the front is. 16. Switching device according to claim 15, characterized in that one longitudinal section (42) together with the rest of the lever (35) is rigid, the other Longitudinal section (41), however, is designed as an attached spring plate. 17. Application of a pressure-dependent switching device according to a of claims 1 to 1b as a low-pressure pressure switch equipped with a membrane as an actuator for a maximum pressure of about 4 - 30 mm WS. 18. Application of a pressure-dependent switching device according to a of claims 1 to 16 as a gas pressure switch (27) connected to a gas line (23) and a downstream solenoid valve when the pressure falls below a limit value (26) switches off.