DE2556289C3 - Electrical switching device with switching differential that is dependent on pressure or another physical variable - Google Patents

Description

The invention relates to an electrical system that is dependent on pressure or some other physical quantity Switching device with adjustable switching differential, in which the movable contact element of a changeover switch from a single actuator, e.g. B. a membrane, actuatable and continuously and freely between two each contact assigned to a limit value is adjustable and one is provided with a self-locking contact Relay controls that excites one contact (excitation contact) when the system is in contact and only when the other contact (de-excitation contact) is de-energized.

In a known switching device of this type (DE-AS 16 65 640) is in series with the self-holding contact a normally closed contact of a second relay that is energized when the moving contact of the Changeover switch touches the de-excitation contact. This switching device calls for both electrical and also in spatial terms a considerable effort. The invention is based on the object of a Specify switching device of the type described above, which has a simpler structure.

According to the invention, this object is achieved in that the self-locking contact is in the energized position located changeover switch is bridged directly and that the movable contact element when it hits the de-excitation contact a bridge the relay-

establishes the short-circuit path.

In this case, a second relay is not required in a space-saving manner, and the electrical structure is simple.

A very simple circuit of this A / t results from the fact that the changeover switch is permanently marked with a point is connected between relay and self-holding contact and the excitation contact with the other side of the Latching contact and the de-energizing contact is connected to the other side of the relay

The relay is de-energized through a short-circuit path bridged. As a rule, the short circuit is harmless because it is caused by the immediate fall of the The relay's self-holding contact only lasts for a short time Arrange a high-resistance resistor in the common supply line and the relay for one accordingly design low response voltage.

If the relay has a switching contact via which a consumer from the same network as the relay is fed, it is ensured with a particular advantage that the switching contact in an AC voltage network directly and the circuit consisting of a resistor, changeover switch, relay and self-holding contact a rectifier and a shunt capacitor are fed. Despite the desired small currents in the The entire switching device can therefore be operated with mains voltage in the area of the changeover switch. An even cheaper solution is obtained if instead of the shunt capacitor one parallel to the relay in the reverse direction switched diode is provided.

In a preferred embodiment, the movable contact element is at least partially resilient formed and beyond the position that the movable contact element assumes when it rests on the excitation contact, a third contact is provided, which is electrically connected to the excitation contact. In this way, the relay is also de-energized when a safety limit value outside of the switching differential limit values is exceeded will. Without giving up the simple structure, there is an additional possibility of functionality.

It is also favorable that the movable contact element is a one-armed lever that is attached to the rear of the actuator and to the front by a Soilwertfeder loaded and arranged with its free end between the excitation and de-excitation contact is, and that the contact on the back is fixed to the housing, the contact on the front to one Adjusting screw attached and a pivot point of the lever by means of one from the front actuating adjusting device is displaceable approximately perpendicular to the lever extension. With the adjusting device one limit value of the switching difference can be adjusted with the adjusting screw the second limit value of the switching difference can be set. Both setting options are accessible from the front of the lever. the entire back can therefore be used for the arrangement of the actuator, for. B. a membrane, are exploited. The terms "front" and "back" refer only to accessibility, not to that Installation position of the switching device · '; nt

In particular, the setpoint spring is supported on a plate secured against rotation, which by means of a secured against axial displacement, from the front to be actuated screw is axially adjustable. The setpoint spring can therefore also be easily adjusted.

In a preferred embodiment, the adjusting device has a screw bolt with one end is attached to a hinge axis guided in grooves parallel to the bolt axis, in one Housing bore is guided and at the other end carries an adjusting nut, and the lever is with lateral Slits pushed over the hinge axis and the bottom of the slot by means of a spring against the hinge axis pressed

A lever forming the movable contact element is particularly advantageous at the free end a longitudinal slot divided into two parallel longitudinal sections and each longitudinal section one on one Adjusting screw attached to the contact on the front. These two contacts correspond to the Excitation contact and the third contact. If the one longitudinal section is already on the associated fixed Contact is applied, if the lever is further stored, this longitudinal section becomes the second, with deformation of this longitudinal section Longitudinal section brought up to the associated fixed contact.

In this context, it is advantageous if the one longitudinal section together with the rest of the lever stiff, the other longitudinal section, however, is designed as an attached spring plate. The stiff longitudinal section is assigned to the third fixed contact, the resilient longitudinal section to the first fixed contact.

The switching device described here can be used for numerous purposes, namely wherever switching devices with switching differential have already been used, z. B. as a pressure switch, Thermostat, travel-dependent switch, etc. Particularly advantageous, however, is the application as with a Diaphragm designed as an actuator low-pressure pressostat for a maximum pressure of about 4 - 30 mm WS. Because at these low pressures it is of the utmost importance for reliable work that no significant forces have to be overcome to operate the switch. A particular advantage It is here that the diaphragm diameter can be reduced considerably while maintaining the travel range and can thus save space. For example, the diaphragm diameter on low-pressure pressostats. which was 100 to 125 mm due to the use of a snap switch, otherwise the same ratios can be reduced by 15 to 30% using the inventive concept. Such low-pressure pressostats are required, for example, in firing systems to control the negative pressure to measure in the chimney or in the combustion chamber, or in the fan housing of a gas burner for the air supply to monitor. Here, the pressostat can control means such. B. throttle plates to the pressure value to keep within the set difference.

An application as a gas pressure switch that is connected to a gas line is also preferred if the dynamic pressure falls below a limit value, a downstream solenoid valve switches off. In this way it is determined that a line break is present and accordingly the Line shut off.

The invention is explained in more detail below with reference to the exemplary embodiments shown in the drawing explained. It shows

1 shows the circuit diagram of the switching device according to the invention and its use as a pressure switch in a furnace;

2 shows the use of the switching device as a gas pressure switch;

F i g. 3 three switch positions of the switch;

4 shows a section through one according to the invention built-up pressostats and

5 shows a plan view of the pressostat according to Removal of the lid.

A relay 1 is connected in series with its self-holding contact 2. A changeover switch 3 has a movable one Contact element 4, which is permanently connected to a point 5 between relay 1 and self-holding contact 2 is. The contact element 4 cooperates with a first fixed contact 6 with a point 7 on the other side of the self-holding contact is connected, as well as with a second fixed contact 8, which is with a point 9 on the other side of the relay 1 is connected. Furthermore, a third can be fixed Contact ok be present, which is connected to the second fixed contact 8 and beyond that position of the Contact element 4 is arranged, which this assumes when contacting the first fixed contact 6. The contact element 4 can be moved continuously by an actuator 11. In the common supply line there is a high resistance 12. Relay 1 is a low voltage relay. The overall arrangement will of two supply lines 13 and 14 supplied with AC voltage via a diode 15 rectified Voltage supplied. A diode 16 polarized in the reverse direction is connected in parallel with relay 1. It ensures that the relay does not drop out despite the supply of unsmoothed direct current. Instead of this diode 16 can a shunt capacitor 16 'can also be used to smooth the direct current. In special cases, the Use of diode 16 and shunt capacitor 16 'possible.

In the illustrated embodiment, the actuator 11 is the membrane of a pressostat that controls the pressure monitored on the output side of a fan housing 17 of a gas firing system. The gas is over a Tube 18 fed. The 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.

It is assumed in the drawing that the movable contact element 4 has just reached the fixed contact 6 has reached. Relay 1 is energized. The self-holding contact 2 closes. The relay 1 therefore remains energized, too when the contact element 4 separates from the fixed contact 6 again. However, if the contact element 4 den Fixed contact 8 is reached, relay 1 is short-circuited. It falls off. This state is retained, even if the contact element 4 separates from the fixed contact 8 again. To relay 1 again excite, the contact element 4 must again assume its position shown. This gives you for the work switch 21 of the relay 1 a switching difference, it goes into the one switching position when that Actuator 11 reaches the upper limit and remains in this switching position until the actuator 11 is the lower Control value reached. Only then does it switch to the other switch position, which is now retained is until the actuator 11 again reaches the upper limit value Achieved in this way a very stable two-point control results, in this case a control of the Air pressure in the fan housing 17.

In the circuit of Figure 2, gas flows from the distribution network 22 via a line 23 to a Consumer 24. In line 23, a pressure regulator 25 and behind it a solenoid shut-off valve 26 are provided. A pressure switch 27 is connected in between. This has a circuit structure as in Fig. 1. During normal operation the solenoid valve 26 is connected to voltage via a contact corresponding to the switch 21 placed. If, however, the pressure drops so far that the contact element 4 makes contact with the second fixed contact 8 reached, the relay I is de-energized and the solenoid shut-off valve is switched off. The same thing happens when the pressure rises above the normal value and the third fixed contact 10 is contacted. If the The line to the consumer breaks and hence the pressure

ίο drops, the solenoid shut-off valve closes. If the Pressure regulator 25 fails and therefore the pressure rises excessively, the solenoid shut-off valve also closes. In contrast, the solenoid shut-off valve remains open within the permissible pressure range because relay 1 is not responds before one of the fixed contacts 8 or 10 has been touched by the contact element 4. Should the fixed contact 8 are only contacted as a result of a brief pressure fluctuation, then but the setpoint specified by contacting the fixed contact 6 can be reached again, that is Solenoid shut-off valve switched on again. The same applies if the overpressure ceases and thereby the overpressure the fixed contact 10 established short circuit is canceled.

3 shows the three positions of interest of the switch 3. The position A corresponds to the lower limit value. The position B corresponds to the upper limit value and the position C corresponds to a safety value lying beyond the upper limit value.

The F i g. 4 and 5 show a practical embodiment of a pressostat according to the invention. A Housing 28 carries a cover 29 on the front and a bottom 30 on the back, the one Has 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 the bottom 30 and the housing 28, which is attached to the Front is stiffened by a pressure plate 33. In this way, a working pressure chamber 34 is created one-armed lever 35 is pivotable about a hinge axis 30, which is controlled by means of an adjusting device 37 is relocatable. It is pressed against a projection 39 of the pressure plate 33 by means of a setpoint spring 38. The lever 35 is made of stiff material and is also between the joint 36 and the adjusting screw 38 stiffened by lugs 40 bent at an angle. The free end of the lever 35 is through two Longitudinal sections 41 and 42 are formed. For this purpose, the longitudinal section 42 is integral with the lever 35 trained and therefore also stiff. The longitudinal section 41, on the other hand, is formed by a riveted leaf spring formed, so resilient. At an inserted. In addition to the relay 1, the circuit board 43 has a contact attachment 44 a fixed contact 45 and two contact arms 46 and 47 each with a set screw 48 and 49 respectively. the Setpoint spring 37 is supported on a plate 50 secured against rotation, which is axially mounted on a screw 51 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 are followed by a socket 55 Outwardly routed The diode 15, the capacitor 16 and the resistor 12 are also mounted on the circuit board 43 The ends of the hinge axis 36 are guided in grooves 56 parallel to one another in the housing also welded on a screw bolt 57 which is guided through a housing bore and at the other end

an adjusting nut 58 carries. In the tab 40 of the lever there are slots 59, the base of which is pressed against the hinge axis 36 by a helical spring 60 will. By turning the adjusting nut 58 of the adjusting device 37, the hinge axis and thus the The pivot point of the lever 35 can be shifted.

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

When an upper limit value is reached, the resilient longitudinal section 41 comes into contact with the

associated adjusting screw 49, which corresponds to the first fixed contact 6. If the pressure increases further, it bends This first longitudinal section 41 extends through until finally the second longitudinal section 42 with the associated Set screw 48 comes into contact, which corresponds to the third fixed contact 10.

All adjustable links are accessible from the front after removing the cover. Means the screw 51 is used to set the printing range as a whole. With the adjusting device 37, the lower • The pressure limit value can be set precisely. The upper pressure limit can be adjusted with the adjusting screws 48 and 49 or the security pressure can be set precisely.

For this purpose 2 sheets of drawings

Claims (13)

1 claims: 1. Electrical switching device dependent on the pressure or another physical quantity adjustable switching differential at which the movable contact element of a changeover switch is controlled by a single actuator, e.g. B. a membrane, actuatable as well as continuously and freely between two each one Limit value assigned contacts is adjustable and one provided with a self-holding contact Relay controls that excites one contact (excitation contact) when it is in contact and only when it is reached of the other contact (de-excitation contact) is de-energized, characterized in that the Self-holding contact (2) directly bridged the switch (3) in the excitation position and that the movable contact element (4) when it hits the de-excitation contact (8) a the Relay (1) establishes bridging short-circuit path. 2. Switching device according to claim 1, characterized in that the changeover switch (3) continuously with a point (5) between relay (1) and self-holding contact (2) is connected and the excitation contact (6) with the other rope (7) of the self-holding contact and the de-excitation contact (8) with the other side (9) of the relay is connected. 3. Switching device according to claim 1 or 2, characterized in that in the common Supply line a high-resistance resistor (12) arranged and the relay (I) for a corresponding low response voltage is designed. 4. Switching device in which the relay has a switching contact via which a consumer powered by the same network as the relay; is, according to one of claims 1 to 3, characterized in that that with an alternating voltage network, the switching contact (21) is direct and the resistor (12), changeover switch (3), relay and self-locking contact (2) existing circuit via a rectifier (15) and a shunt capacitor (16 ') are fed. 5. Switching device according to claim 4, characterized in that instead of the cross capacitor a diode (16) connected in the reverse direction parallel to the relay (1) is provided. 6. Switching device according to one of claims 1 to 5, characterized in that the movable Contact element (4) is at least partially resilient and that beyond the position that the movable contact element when it rests on the excitation contact (6), a third contact (10) is provided, which is electrically connected to the de-excitation contact (8). 7. Switching device according to one of claims 1 to 6, characterized in that the movable Contact element (4) is a one-armed lever (35) on the back of the actuator (membrane 32) and loaded on the front by a setpoint spring (38) and with its free end between Excitation and de-excitation contact is arranged, and that the contact (45) on the back fixed to the housing, the contact on the front is attached to an adjusting screw (48, 49) and a Articulation point (36) of the lever (35) by means of an adjusting device to be operated from the front (37) can be displaced approximately perpendicular to the extension of the lever. 8. Switching device according to claim 7, characterized in that the setpoint spring (37) is attached a secured against rotation plate (50) is supported, which by means of an against axial displacement secured, from the front to be actuated screw (51) is axially adjustable 9. Switching device according to claim 7 or 8, characterized in that the adjusting device (37) has a screw bolt (57) which has one end at a parallel to the bolt axis Groove (56) guided joint axis (36) is attached, is guided in a housing bore and on the other End carries an adjusting nut (58), and that the lever (35) with lateral slots (59) over the hinge axis is pushed and the slot base is pressed against the hinge axis by means of a spring (60). 10. Switching device according to one of claims 6 to 9, characterized in that a lever (35) forming the movable contact element (4) is divided at the free end by a longitudinal slot into two parallel longitudinal sections (4i, 42) and a contact attached to an adjusting screw (48, 49) on the front of each longitudinal section assigned. 11. Switching device according to claim 10, characterized characterized in that the 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 Federhlech. 12. Application of a pressure-dependent switching device according to one of claims 1 to 11 as a low-pressure pressostat equipped with a membrane as an actuator for a maximum Pressure of about 4-30 mm WS. 13. Application of a pressure-dependent switching device according to one of claims 1 to 11 as a gas pressure switch (27). the one on a gas pipe (23) is connected and if the pressure falls below a limit value, a downstream solenoid valve (26) switches off.