EP0339269A1 - Switchgear for heating appliances or the like - Google Patents

Abstract

In a switchgear (1) for the variable power operation of a heating applicance (2) or the like, with the aid of a control device (8) operating in a pulsed manner, the operating element (11) is designed such that it switches off a control heater (10) of the control device (8) not only in the switched-off position but also in higher adjustment regions and in the highest adjustment region (16) and does not switch on until lower adjustment regions (17, 18) are reached and in the event of manual switching over of the switchgear (1) from the highest adjustment region (16) to a lower adjustment region (17, 18), the pulsing cycle is forced to start with a switched-on position of the energy switching contact (6). In consequence, the switchgear (1) is especially suitable for the operation of low capacitance heating appliances, such as microwave appliances, and can be produced simply by redesigning a cam disc (13) of the operating element (11) of previous switchgears. <IMAGE>

Description

The invention relates to a switching device for heating devices or the like. According to the invention, in order to achieve a favorable switching sequence, it has a switching contact that can be influenced by at least one actuator.

Furthermore, the invention relates in particular to a switching element with an actuating element which can be set in different operating positions to lower and higher setting ranges for influencing an energy switching contact, via which the device to be operated is to be supplied with current in at least one setting range by intermittent switching on and off. The switching device expediently has a control device which determines the switching cycle and can, if necessary, be adjusted to change it, by means of which the energy switching contact is added play is affected from reaching each of its two switching positions towards the other switching position, which it then reaches with a corresponding delay by suddenly switching from the first-mentioned switching position. By adjusting this delay, the relative duty cycle of the energy switching contact can be changed, which is defined by the ratio of the duty cycle to the total operating time. The aforementioned influencing of the energy switching contact is caused by the gradual charging or gradual discharge of a control element, for example a thermoelectric pulse generator, such as a bimetallic element with associated control heating, which is used for heating, but in particular also for cooling, due to the thermal conditions, for example its storage capacity. Conductivity and the like require a relatively precisely determinable amount of time.

In the case of known switching devices, this measure of time is generally considerably more than one minute and is therefore advantageous for devices which, due to the technical design, only change their operating state gradually after the switching position of the energy switching contact has changed. This is the case, for example, with electric hot plates with a cast iron hotplate body or other heating devices with a relatively high heat capacity, since these do not cool suddenly after opening the energy switch contact, but only with a relatively large time delay and therefore only one until the energy switch contact is closed again suffer relatively little temperature loss. If such a switching device is set, for example, to the highest power level, which in practice corresponds to at least approximately 100% relative duty cycle, the control heating is in operation, but the deflection of the bimetallic element caused by this is not sufficient to open the energy due to its setting by the actuator -Switch contact. If the corresponding power level is now reset via the actuator to a lower, for example about 20% relative duty cycle, the control heater is simultaneously switched to its other state, namely switched off in the illustrated case, but this does not have an immediate effect on its control state since the control heater and the bimetallic element require the specified time for cooling. Before this cooling has taken place, the control state is such that the energy switch contact remains open due to the interaction between the control device and the actuator or the power supply to the device to be operated is interrupted. In the case of the heating devices mentioned, however, the heating device only cools down correspondingly slowly to an operating temperature during this time, which corresponds to the newly set, lower power level.

Such a switching device is disadvantageous for low-capacitance or essentially capacitance-free devices, however, if after switching back from a higher power range to a lower power range, no break in operation is desired. In the case of, for example, heating devices, these suddenly cool after an interruption in the power supply, while the control device, because of its capacity delay, requires the stated time to change its state and thus to switch the power supply back to the heating device, so that after the switch-off, the heating device continues to operate immediately the lower power level is not possible, but there is an undesirable switching or operating break.

The invention is also based on the object to provide a switching device of the type mentioned, in which the disadvantages of known designs are avoided, it should be possible in particular in a simple manner, according to the Switching down from a higher setting range to a lower setting range means that the power supply of the device to be operated can be continued with very little or no pulse pause. As a result, the switching device should be particularly suitable for the control or regulation of microwave devices.

This object is achieved in a switching device of the type mentioned according to the invention in that the control device in the higher or highest setting range does not act in its operating state, which acts to interrupt the power supply of the device or the switch-off position of the energy switching contact, but in its initial state ( eg when the control heating is switched off), in which it also influences the energy switch contact to its switch-on position associated with the power supply of the device or, in addition to the actuating element, the control device also holds the energy switch contact in the switch-on position. If the actuator is now reset to one or the lower power level, the energy switching contact is influenced by the actuator to move in the direction of its switch-off position, but is still held in the switch-on position by the control device (e.g. when the control heating is still cold) however, at the same time the state of the control device (e.g. by switching on the control heating) is switched to the start of a switch-off cycle, so that the control device now begins to influence the energy switching contact in the direction of the switch-off position (e.g. by the temperature rise in the control heating) until the first switching process after this provision for benefits. After a power reset, the duty cycle of the switching device or control device does not begin as before from a switch-off position (e.g. through a heated control heater) with a switch-on process (e.g. by switching off and cooling the control heater), but vice versa returns from a switch-on position (cooled control heating) with a switch-off process (heating control heating), so that practically a continuous power supply of the device to be operated is possible when the power level is reduced.

In the case of a control heater, which is arranged so that it is heated to carry out the switch-off process, this control heater is switched off in the higher power level and it is switched on again when the power level is reset to the lower power level, so that it reaches its switching temperature With a corresponding time delay, the energy switch contact is brought into the switch-on position and then continues to operate accordingly. However, it is also conceivable to arrange the control device in such a way that the control heating or the bimetallic element, when it cools down, causes the energy switching contact to be switched off.

The control device expediently has a clocked operating control circuit which is provided with a control circuit switch contact clocking in at least one lower setting range, in particular in all lower setting ranges, for switching the control heating on and off in a delayed alternating cycle. This control circuit switch contact can be formed by a separate contact, but is expediently formed in a simple manner directly by the energy switch contact, so that the power supply to the device to be operated and to the control heating is switched on and off simultaneously.

In addition to this control circuit switching contact, at least one separately operable control switching contact is expediently provided in the control circuit, with which the circuit of the control circuit can be interrupted or possibly closed independently of the control circuit switch contact. At least one of these switch contacts or control switch contacts could be bridged independently of the actuator with a manually operable switch, so that either the operation described with the aid of higher capacity as well as with the aid of low capacity devices is possible. In a simple embodiment, the control switch contact is inevitably actuated via the actuating element, so that the switching state of the control loop is determined in precise dependence on the selected setting range. If the switching device already has a switching contact actuated by the actuator, which is open in a zero or switch-off position of the switching device, then this switching contact can also be used as a control switching contact in that, in addition to the switch-off position, it can also be used in the higher or highest setting range corresponding position of the actuator is open and in the lower setting range or in all lower setting ranges is closed or in the switching state which is provided for the clocked operation of the control device.

The higher or highest setting range of the actuating element is expediently immediately adjacent to the switch-off position after one operating direction and adjacent to the setting ranges continuously decreasing to the switch-off position. The control device can therefore be held continuously in the initial state between the higher or the highest setting range and the switch-off position, or can be switched in the opposite direction between the next lower setting range and the switch-off position in the operating state by actuating the actuating member.

The actuator can have handlebars, push rods or the like for influencing the control device and possibly the control switch contact, but this results in a particularly simple design if at least one for this Cam disk is provided, which is expediently a circumferential cam disk instead of a front cam disk. This can thus be arranged directly and in a rotationally fixed manner on an actuating shaft which directly carries an actuating handle, for example an adjusting knob, outside a device housing receiving the contacts and the cam disks. The arrangement described also results in a very compact, reliable, trouble-free and easy-to-adjust design. Furthermore, the design according to the invention can also be subsequently carried out in a simple manner on already existing switching devices in that only one cam disk is changed or replaced, namely that which influences the control switch contact.

• Fig. 1 einen Schaltplan für ein gemäß der Erfindung mit einem Schaltgerät zu betreibendes Wärmegerät,
• Fig. 2 das Schaltgerät in Axialansicht bei geöffnetem Gehäuse und
• Fig. 3 einen Querschnitt durch das Schaltgerät gemäß Fig. 2 jedoch bei geschlossenem Gehäuse.

These and further features of preferred developments of the invention are evident from the claims and also from the description and the drawings, the individual features being implemented individually or in groups in the form of sub-combinations in one embodiment of the invention and in other fields, and can represent advantageous and protectable versions for which protection is claimed here. An embodiment of the invention is shown in the drawings and is explained in more detail below. Show in the drawings

• 1 is a circuit diagram for a heater to be operated according to the invention with a switching device,
• Fig. 2 shows the switching device in axial view with the housing open and
• Fig. 3 shows a cross section through the switching device according to FIG. 2 but with the housing closed.

As shown in FIG. 1 in particular, a switching device 1 according to the invention is used to operate a single-circuit or multi-circuit device, in particular a heating device 2, the energy emitter of which, which can be formed, for example, by a high-frequency transformer 3, a radiant heater, an exposed tubular heater or the like, serves a relative purpose has low energy storage capacity. The energy emitter is arranged in an energy circuit 4, which is controlled and possibly regulated by a control circuit switched by a thermoelectric control circuit.

An energy switching contact 6 in the form of a snap contact is arranged in the energy circuit 4. The control circuit 5 is connected on the one hand between this energy switching contact 6 and the heating device 2 to the one feed line and on the other hand to the other feed line. In the control circuit 5, a simple, mechanically switchable control switch contact 7 and a thermoelectric control device 8 or its control heater 10 are connected in series therewith. This control heater 10 acts on a thermomechanical control element, for example a bimetal element, which actuates the energy switch contact 6.

In addition to the control device 8, the energy switch contact 6 can also be manually operated directly, but the mechanical actuation connection includes the control element 9, so that this remains theoretically always effective, but practically in at least one setting of the actuation element 11, for example in its switch-off position Switching function of the control device 8 or of the control element 9 is overridden in such a way that the power switch contact 6 is not switched on despite the switch-on state of the control device 8.

The actuator 11 has on a 360 ° rotatable actuating shaft 12 two axially directly adjacent to each other cam disks 13, 14, one of which, in its radial expansion much smaller or smaller compared to the smallest radial expansion of the other cam 14 14 for direct mechanical Actuation of the control switching contact 7 is used, while the other is provided as an adjusting cam 14 for the indirect actuation of the energy switching contact 6 with the interposition of the control element 9. This adjusting cam disk 14 has a radially most protruding shut-off cam 15, a highest adjustment area 16 lying directly adjacent to it in the circumferential direction and having the smallest radial distance from the axis of rotation, as well as a continuously decreasing adjustment area 17 extending from this to the other flank of the shut-off cam 15 on, which is determined by an eccentric cam track with a greater radial distance from the setting area 16 or from the shut-off cam 15 with increasing distance and immediately adjacent to the associated flank of the shut-off cam 15 forms the lowest setting area 18, which corresponds, for example, to a relative duty cycle of 20%. While the arrangement according to FIG. 1 is provided in such a way that it is switched from the switched-off state to the lowest setting range 18 by turning clockwise, an arrangement is also conceivable in which the cam disks are designed in such a way that this direction of rotation is counterclockwise.

With a fraction of about a fifth of its total circumference, the cam disk 13 forms a partial actuating path 19, on which the control switch contact 7 is in the output circuit, namely is open. The rest of the cam track of the cam 13 is pitch-free, namely cylindrical, and the control switch contact 7 is inevitably mechanically closed on the partial actuation path 20 formed thereby.

The partial travel 19 is only effective with respect to the control switch contact 7 if the switch-off cam 15 or the setting range 16 and possibly a subsequent part of the setting range 17 of the cam disk 14 are effective with regard to the power switching contact 6. If the setting range 16 is effective, the adjustment can be made in such a way that the switching function of the control device 8, namely the energy switching contact 6, is automatically mechanically closed, which equates to a relative duty cycle of 100%. The control device 8 acts with the interposition of a control arm 9 including the link 26 mechanically directly on a movable, influenced by a snap spring contact part 22 of the energy switching contact 6. Via this link 26, the adjusting cam 15 acts on the contact part 22, for which the handlebar 26 adjustable and resiliently resilient with a prestress on the cam track of the adjusting cam disk 14 with a position 24, for example, with an adjusting screw. With a corresponding rotor 25, a movable contact part 23 of the control switch contact 7 is resiliently supported on the associated cam disk 13 with pre-tension, whereby this rotor 25 can be bent out of the contact part 23 in one piece.

At least in the switch-off position, the actuator 11 is fixed by a resilient catch, which is caused directly by the engagement of the rotor 24 and / or the rotor 25 in the actuator or by a recess in the apex of the switch-off cam 15 or at the associated end of the partial adjustment path 9 the cam disc 13 may be formed. In the exemplary embodiment shown, the catch 2l is formed by a depression in the cam track of the cam disk 13, this depression forming the area of the cam track with the smallest radial distance from the axis of rotation and the partial adjustment path 19 of this catch 2l in the direction of the highest setting range 16 associated direction gradually increases, while the rest 2l directly adjoins the slope-free partial travel 20 in the other direction. In the area of the transition away from the detent 21 or the switch-off position between the partial actuating path 19 and the partial actuating path 20, the cam track can still form a small step, so that there is also a detent with a relatively low detent force for this highest setting area 16 and the changeover from the higher setting range to the lower setting range 17 or from the open to the closed control switch contact 7 can be felt by the operator. The correspondingly recessed adjustment range 16 of the cam disk 14 can also form a corresponding catch.

If the switching device 1, for example, is switched from the switched-off state to the highest setting range 16, the control switch contact 7 remains open and thus the control device 8 is de-energized, that is to say in the initial state, so that the control element 9 does not heat up and therefore also not to its switched-off position for the Energy switching contact 6 is deflected. If the switching device 1 is then switched from the highest setting range 16 to a lower or the lowest setting range 18, the control element 9 is for this reason in its cooled operating state associated with the switch-on position of the energy switching contact 6, which is why the clocking control cycle in this case begins with the closed or switched-on position of the energy switching contact 6 and not as previously with the open or switched-off position. Since the energy switch contact 6 is also provided as a control circuit switch contact and therefore in its switched-on position sets the control device 8 into the operating state, the control element 8 begins to deflect at the beginning of this initial cycle and, after a corresponding timeout, the control loop and energy switch contact 6 to open and then in the further course to close and open again so clocked that the desired relative duty cycle is given. As a result, when switching from the higher setting range 16 to the lower setting range 17 it is achieved that the energy emitter of the heating device 2 or the like is supplied with current continuously or uninterruptedly during the changeover and for some time thereafter.

2 and 3 show a particularly advantageous functional and spatial configuration of the switching device 1. All functional parts of the switching device 1 are arranged in a rectangular or square and flat housing 27 between two end walls, one of which is designed as a plate-shaped or plate-shaped carrier 28, on which all functional parts are essentially at right angles to the carrier 28 from the inside thereof by plug connections forth are mounted in such a way that they form on the outside of this carrier 28 all connection plug-in elements, namely tabs of the switching device 1. Each fixed contact part directly forms at least one plug-in member, while each movable contact part is arranged on a contact carrier, which in turn forms at least one plug-in member.

The contact carrier 29 of the energy switching contact 6, like its movable contact part 22, lies essentially parallel to an adjacent outer edge of the carrier 28 made of insulating material and immediately adjacent or tangential to the actuating member 11. The movable contact part 22 is on the side facing away from the actuating member 11 of the contact carrier 29 with the interposition of the snap spring 30 attached such that it can be moved between the switch-off position shown in FIG. 2 and a switch-on position in which its contact head is in conductive contact with an opposite fixed contact part 31 which is on the side facing away from the contact carrier 29 Side of the contact part 22 is provided.

For clocked actuation and for setting to different power ranges, the approximately right-angled angular link 26 with a leg end, which forms the runner 24 with the end of its other link leg 33, engages on the side of the movable contact part 22 facing away from the contact carrier 29. This handlebar leg 33 is bifurcated, with a resilient fork arm forming the rotor 24 and the other fork arm adjustably carrying an adjusting member 36 in the form of a stud screw, which rests on the side of the V-shaped rotor 24 facing away from the cam disk 14, lying approximately radially to the actuating member 11 and therefore can adjust the handlebar 26 relative to the rotor 24 about the handlebar axis or handlebar shaft 32 lying in the transition region of the handlebar legs. The two handlebar legs lie essentially parallel to two outer edges of the carrier 28 lying at right angles to one another in its associated corner region, in which the handlebar shaft 32, which is supported in both end walls, is located, as is the actuating shaft 12. The other, essentially parallel to the movable contact part 22 handlebar leg is essentially formed by the flat strip-shaped control member 9, the free end facing away from the handlebar shaft 32 is curved to the associated end facing away from the contact head of the movable contact part 22 and on the side facing away from the contact carrier 29 Side of this end with a pressure cam 34 under bias. The control heater 10 is located directly adjacent to a longitudinal section of the control element 9 essentially adjoining the control shaft 32 on its side facing away from the energy switching contact 6. The movable contact part 22 is essentially formed by a leaf spring-like element. The control member 9 deflects under heating by the control heater 10 in the direction of the actuator 11 and takes the associated end of the contact part 22 with the pressure cam 34, whereby the contact head due to the action of the leaf spring 30 after reaching a predetermined deflection of the control member 9 in snapped in the same direction from the fixed contact part 31 and is placed against a stop provided on the contact carrier 29.

The control switching contact 7 is provided on the side of the actuating member 11 or the actuating shaft 12 facing away from the energy switching contact 6, its movable contact part 23 likewise lying approximately parallel to the same outer edge as the contact part 22 of the energy switching contact 6. A fixed contact carrier 38 carries one end of the contact part 23 designed in the manner of a leaf spring arm, the other end of which lies opposite an associated fixed contact part 37, this contact part 37 being provided on the side of the contact part 23 facing away from the actuating member 11. From this contact part 37, a feed line formed by an angled piece of wire leads to the carrier of a sliding contact 35, the long, round, bush-shaped carrier of which is held by insertion into both end walls of the housing 27. The freely protruding sliding contact 35, formed by a leaf spring arm formed in one piece with its carrier, rests with a skid surface against a mating contact of the control heater 10, which is provided on its side facing away from the control element 9 and in the region of the end of the control heater 10 facing away from the handlebar shaft 32 . The control circuit thus goes from the contact carrier 38 through the contact parts 23, 37, the feed line 39, the sliding contact 35, the control heater 10, the control element 9, the contact part 22 and the contact carrier 29. The energy circuit, on the other hand, goes through the contact carrier 29 , the contact part 22 and the contact part 31.

The switching device 1 expediently has at least one further switching contact 40, which is expediently provided on the side of the control switching contact 7 facing away from the actuating element, and its movable contact part 41 arranged on a contact carrier essentially by means of a closed at least one of the further movable contact parts parallel arm is formed. The contact head of the movable contact part 41 is opposite a fixed contact part 42 on the side facing away from the actuator 11. The movable contact part 41 could be actuated by contact with a rotor directly through one of the cam disks or another separate cam disk of the actuating member 11, but in the exemplary embodiment shown is actuated via the movable contact part 23 of the switching contact 7, the contact part 23 of which is pretensioned on the contact part 41 has adjacent carrier 43. The driver 43 can instead be attached to the contact part 41 and rest on the contact part 23.

The switch contact 40 can be provided, for example, as a signal switch contact in order to make the operating state of the heating device 2 or the like clear via a corresponding display. In this case, it is expedient if the switching contact 40 is adjusted so that it opens when the switching device 1 is switched off by the switching cam 15, but when changing over to the higher or highest setting range 16, that is to say with the control switching contact 7 still open, is already closed. For this purpose, the partial adjustment path 19 formed by the cam disk 13 can be designed such that it closes the switching contact 40 and opens it, for example, only in the switch-off position defined by the detent 21.

Claims (11)

1. Switching device for heating devices or the like., Characterized in that it has at least one switching contact (6) to be influenced with an actuating element (11). 2. Switching device according to claim 1, with an actuator (11) adjustable in different actuation positions to higher and lower adjustment ranges (16, 17, 18) for influencing an energy switching contact (6) which is in at least one of the lower adjustment ranges (17, 18th ) is operated with an associated relative duty cycle via a control heater (10) switched by a heater switch contact (6) in such a manner that the energy switch contact (6) is in an operating state of the control heater (10) to an off position (FIG. 2) and in an initial state of the control heater (10) is influenced to an on position, characterized in that the control heater (10) has at least one actuating position of the actuating member (substantially including the higher setting range (16)) 11) is in the initial state. 3. Switching device according to claim 1 or 2, characterized in that in a circuit (5) of the control heater (10) in addition to a clock operating in operating setting ranges, in particular formed by the energy switch contact, control circuit switch contact (6) in particular A series with the control heating (10) or this control circuit switch contact (6) and between an operating switch position and an output switch position (Fig. 2) operable control switch contact (7) is provided, which preferably includes the higher setting range (16) Operating position of the actuator (11) is open. 4. Switching device according to one of the preceding claims, characterized in that the control heating (10) over a to the highest setting range (16) adjoining partial travel (19) of the actuator (11) in the output circuit (Fig. 2) and that this partial travel (19) corresponds to a fraction, in particular at most a fifth, of the total travel of the actuator (11). 5. Switching device according to one of the preceding claims, characterized in that the actuating member (11) from its higher setting range (16) associated actuating position essentially without rest in one Actuating direction subsequent actuating positions can be transferred, in which preferably the control switch contact (7) is closed. 6. Switching device according to one of the preceding claims, characterized in that the energy switching contact (6) with the actuator (11) in a switch-off position (Fig. 2) can be transferred, in which the control switching contact (7) preferably also in one The initial switch position is set, in particular the control switch contact (7) being continuously in the initial switch position via a partial adjustment path (19) of the actuating element (11) that includes the switch-off position and the higher setting range (16). 7. Switching device according to one of the preceding claims, characterized in that with the actuating member (11) a movable contact part (22) of the energy switching contact (6) via a control element (9) influenced by the control heating (10) mechanically switching Switching element, in particular a circumferential cam disk, is connected to at least one switch-off cam (15) and / or a cam track forming the setting areas (16, 17, 18). 8. Switching device according to one of the preceding claims, characterized in that a movable contact part (23) of the control switching contact (7) preferably directly mechanically switching switching element, in particular a cam plate (13), such as a circumferential cam plate is connected to the actuating member , which is preferably arranged directly on an actuating shaft (12) of the actuating member (11) or adjacent to the adjusting cam (14) for the adjusting areas (16, 17, 18). 9. Switching device according to one of the preceding claims, characterized in that the control switch contact (7) with the same switching element can be transferred to all starting switching positions, preferably two mutually offset, part-actuating paths (19, 20) determining cam parts on the otherwise substantially pitch-free cam (13) are provided. 10. Switching device according to one of the preceding claims, characterized in that at least one end of the cam path of the higher adjustment range (16) associated part-adjustment path (19), in particular in the direction of the lower adjustment range (17) towards the end, rising flat in the cam path which forms the subsequent, essentially pitch-free partial travel (20) and that preferably the other end of the partial travel (19) associated with the higher setting range (16) into a switch-off latch (21) for the actuating member (11) transforms. 11. Switching device according to one of the preceding claims, characterized in that the actuating member (11) is mounted essentially exclusively rotatably and the switching contacts (6, 7, 40) on a carrier (28) are arranged within a housing (27).

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