NO143248B - POWER STEERING APPARATUS. - Google Patents

Abstract

Power control device.

Description

The invention relates to a power control device for the controllable supply of electrical power in power pulses to a consumer, with a heated depending on the connected power, pivotably stored bimetallic element which acts on a snap switch via an angularly projecting arm, and with a compensating bimetal,

and a cam disc which is rotatable by means of a setting shaft.

Such a power control apparatus is known from the publication "Conti-Electro-Berichte", October/December 1959, pages 285 to 290, see in particular fig. 3. This power controller has a bimetal to which a compensating bimetal joins at right angles. In the area near the inner corner, this ddbbelt bimetal is pivotably supported on a pin placed in the switch base. The compensated ionic bimetal acts on a encapsulated switch. Regulate^ none occurs by means of a cam disk which, over a roller and a specially stored arm as well as an adjustment screw, acts on the free end of the work-eids bimetall. Opposite the bimetal is a mechanical switch with contact springs.

In this power control device, for constructive reasons, the bimetal can have a length that is only slightly greater than half the switch dimension. In accordance with this, its thickness dimension and working distance are therefore smaller. The bimetal's temperature is further transferred to the directly connected compensating bimetal, so that this always works in an area with a relatively high temperature and can therefore only incompletely solve its own task, namely to take into account ambient temperature effects. The setting of the working area by means of a swing of the working bimetal with a lever mechanism is complicated and leads to the reproducibility of the individual partial effects not being accurate. Above all, this reproducibility is poor in the critical upper and lower power ranges. A partial effect of, for example, 5%, which is necessary to be able to heat on an electric hob, cannot be achieved with certainty with such an appliance. There are, for example, from German patent document No. 16 40 084 power control devices with a pivotable snap switch. With these, the working bit metal is directly connected to the snap spring and the control takes place via a cam disc and an arm with a stop, whose distance to the working bit metal changes during the setting. This system only allows relatively thin and labile bimetals and makes it difficult to apply a (not provided for in the publication) compensation.

The purpose of the invention is to provide a power control device which has a small and compact design, can be easily manufactured and which, despite relatively small requirements for precision in the construction, enables a very good reproducibility of the power settings. In particular, the compensation of the ambient temperature must be solved in a reliable way.

According to the invention, this is achieved by the snap-on switch being pivotably stored as a unit together with the switch carrier and the compensating bimetal fixed on one side and essentially parallel to the snap-on switch on the shutter carrier, with the cam disc acting on the free end of the compensating bimetal to swing this unit, while the essentially L-shaped bimetallic element is pivotable independently of the pivotable snap switch/compensation bimetal unit.

There is thus provided a unit consisting of compensating ion bimetal and snap switches which can be swung as a unit. The compensation bimetal is only slightly affected by the temperature of the working bimetal and can therefore better take care of its compensation task. In addition, the compensating bimetal is also heat-shielded by means of the parallel-arranged snap shutter. The compensation bimetal can be made short and relatively powerful. The working bimetal, on the other hand, maintains its position and swings one end towards the snap switch in accordance with the heating.

Preferably, the bimetallic element's longest leg is provided with a heater and is possibly supported against the housing by means of an adjustment screw and a spring force.

According to the invention, a diode can advantageously be arranged in a device powered by alternating current, as this diode is only switched on for the bimetallic heating in the upper power range and is switched off in the lower power range by means of a switch operable by the setting shaft.

A relatively coarsely dimensioned bimetallic heating can therefore be arranged, which can therefore also be more easily controlled by the thickness of the wire. In the lower power range, this heating is fully effective, so that you get a rapid heating of the bimetal, so that you achieve a rapid disconnection of the total power. The short relative switch-on time thus achieved will also keep the heating of the switch within certain limits, as the bimetal control heating is only switched on during the switch-on of the consumer. In the upper power range, on the other hand, which can for example start at 20% relative switch-on time, the diode is switched on before the bimetal heating. The heating of the bimetal then only gets half a wave of alternating current and thus only half the effect. The heat generation is thereby also reduced and it is easier to control the higher effects. In this area, the development of heat would be particularly troublesome, because here there is also a high switch-on time for the bimetallic heating. Furthermore, the temperatures at the bimetal are kept low and the total switch heating is small, so that you also get an advantageous compensation option for the ambient temperature.

It is particularly advantageous to arrange the diode at the rear of the housing of the power control device, directly at the switch that is overvoltage. Such an embodiment facilitates the arrangement and connection of the diode, and the diode will be arranged in a cool outer area of the switch. The switch that engages the diode can be a simple creeping operating switch that does not require any spring mechanism in the setting shaft.

Further advantages and features of the invention will emerge from the claims and from the description in connection with the drawing.

An embodiment of the invention is shown in the drawing and will be explained in more detail below with reference to the drawing, where: Fig. 1 shows a plan of a power control device according to the invention, seen from the operating side, and with the lid removed,

Fig. 2 shows a section along the line II-II in Fig. 1,

Fig. 3 shows the back of the power control device, set

from the left in fig. 2,

Fig. 4 shows a schematic connection diagram for the power control device in fig. 1-3.

In fig. 1-3 shows an embodiment of a power control device 11. The device includes a rear housing part 12 made of plastic, in the form of a right-angled or preferably square block with an internal recess 25. This recess can be closed on the operating side with a lid 13. The lid 'has centering pins 17 intended for engagement in the centering holes 16

in the housing part 12. A threaded sleeve .14 is attached to the lid 13, through which a setting shaft 15 is guided. The setting shaft 15 has a in fig. 4 indicated setting button 60. The setting shaft 15 projects into a central hole 23 in a control body 18. The control body is made of an insulating material and carries

on its outer circumference a cam disc'19 and a cam 20. At its rear end, the guide body 18 has a bearing pin 21 which enters an opening 24 in the rear housing part 12 and on the back of the housing part 12 has a further cam 22.

A compensating bimetal 26 in the form of a transfer arm interacts with the .kiurveski vptj 19. The compensating ion bimetal is pressed with its front inclined end against the control curveh 19 by means of a spring 34. The relatively thick and rigid compensating bimetal is at the end, where it does not lie against the control curve 19, pivotably supported by means of a pivot axis 28. At this end, the compensating bimetal is connected to a switch carrier 29

in a snap switch 27, so that the compensation bimetal extends at a small distance from and parallel to the switch carrier 29. The snap switch-compensation bimetal unit can therefore swing about the axis 28.

On the switch carrier 29, a snap spring is placed, which rests against a support bearing in the usual way by means of an inclined spring tongue under buckling stress. At its free end, the snap spring has a contact 31 intended for cooperation with a fixed counter contact 32, and at its opposite end is affected by an adjustment screw 33. The adjustment screw has a circumferential incision into which the fork-shaped snap spring end is inserted. By welding on a contact end leading to the electrical line 35, the snap spring is electrically connected to the consumer's 70 output or input 68.

The snap switch 27 is operated by a bimetallic element 36,

which is L-shaped. The entire L1 consists of bimetal, and in the inner angle of the L there is attached an axis 37 which, in the same way as the axis 28, is advantageously fixed in that in the respective housing

the part 12 and the lid 13 are provided with recesses which accommodate the axes when the housing parts are put together.

The long heated leg 38 of the bimetallic element 36

has a heating coil 39 which is supplied with current through two wires.

At the free end, an adjustment screw 40 is screwed into the heated leg 38, which is pressed by a spring 41 against an intermediate wall 42 in the housing 12.

The bimetallic element 36 has a short leg 43 at its end

a bend 44 that presses against the snap spring 30's operating point.

The heated leg 38 of the bimetallic element 36 lig-

ger in one of the intermediate walls 42 partially closed, and through air-

openings 45 ventilated room 71.

The snap switch/compensation bimetal unit and the bimetal element 36 have, as mentioned, an angular shape and between these components a control body 18 is arranged. In the opposite corner of the room 25, a mechanical switch is arranged including a pusher 50 which is operated by the cam 20. This of a pushers made of plastic have the shape of a square rod, one end of which is rounded for cooperation with the cam 20, and the other end of which is affected by a compression spring 54. The pusher 50 runs approximately diagonally in the housing, so that it can have the greatest possible length.

The pusher has protrusions on its upper and lower surfaces

51 which form counter bearings for contact arms 52, 53. These contact

arms are pushed onto the pusher and protrude from both sides.

The pusher 50 preferably consists of an insulating part, so that the contact arms can be pushed onto it and secured by snapping.

Each contact arm has a contact at each end.

The pusher 50 is controlled by guides 55 which are designed as

from the bottom of the housing part 12 projecting, and metal plates aligned across the pusher. Four guides 55 are arranged, two and two being directly opposite each other. These guides ensure a steering or guiding of the pusher and partially grip around it. The guides 55 carry partially fixed contacts 56 and pass through the bottom of the housing part 12 and form at the back connection tabs of the same type as AMP plug tabs.

The back of the power control device 11 is shown in fig. 3.

It can be seen from this figure that the comb "22 cooperates with a very small and light switch 61 in the form of a contact spring which is designed for short-circuiting a diode 62. The diode's contacts 63, 64 are directly soldered to the corresponding contact plug respectively contact spring, and the contact spring extends around the diode in such a way that it can short-circuit it when contact 64 is touched.

The power control device works in the following way:

In fig. 1 shows the disconnected state, where the cam 20 presses the pusher 50 against the force of the pressure spring 54 and the contact arm 52 for the signal contact and the contact arm 53 for disconnecting the second connection pole are lifted from the corresponding fixed contacts. In this position of the control body 18 and the setting shaft, respectively, the compensating bimetal 26 will lie in a recess on the cam disc 19, so that a locking effect is obtained.

When the energy regulator is switched on (turning the control body 18 clockwise) the cam 20 will first release the pusher 50 and this will then, under the influence of the force from the spring 5 4, displace so that its at least partially springy contact arm 52, 53 rests against the guides 55 Thereby, firstly, the signal contact line 66, 67 is closed, and also one pole of the consumer 70 is closed. The consumer 70 can e.g. be an electric hotplate.

Under the influence of the spring 34, the unit will then move to a position determined by the cam disc 19• The contact 31 and 32 are closed, and the bimetal element 36 is heated with its heating winding 39. The switch 61 is closed in the lower power range, for example at a position of the setting shaft that corresponds to power values of between 5 and 20% of the total power. If the power is set to low, that is

the diode 62 short-circuited, so that the heating winding 39 is fully

effective. The leg 38 of the bimetallic element will therefore bend relatively quickly and, via the short leg 43 and the bend 44, will press on

the snap switch so that it opens again after a relatively short time.

After the cooling of the bimetallic element, the snap switch 27 will again be engaged and the work cycle will begin again. In the upper working area, firstly, the compensating bimetal/snap switch unit is turned more clockwise, and secondly, the diode is active because the switch 61 is open. The heating 39 is therefore only operated with a half-wave of alternating current, i.e. with half heating effect. The bimetallic element thus needs significantly longer time for a deflection which causes the snap switch to open and thus disconnection of the power supply to the consumer 70. At the resulting relatively high temperatures of the bimetal, the cooling will also be faster, so that a higher relative switch-on time is ensured.

The power control device according to the invention has several advantages: Despite the clear and reliable structure, it can be produced in a relatively simple way, and it works with relatively large coupling paths and forces. The big forces in particular are essential. These are achieved as a result of a relatively strong bimetallic dimensioning. As a result of the favorable structure, the working bimetal can be made relatively long, while the compensation bimetal is made relatively short and strong. The springs 34, 41 enable the entire system to be moved in a force-locking manner to a specific position, so that there is only one point where clearance can occur, namely the point of contact between the snap spring 30 and the bend 44 on the working bimetal 36. The design of the bimetal element 36 which The L-shaped element of bimetallic material also has a further advantage. Normally, the compensation in such a control device using a compensating bimetal presents difficulties, because the two bimetals work in different temperature ranges. The bending distance of a bimetal per however, the temperature unit decreases with increasing temperature, so that the compensation can always only be accurate for a working range. However, the bimetallic element described here has, so to speak, a double heating. The short leg 4 3 extends for a relatively small distance parallel to the spring 30. This is supplied with current through the contact 3 5 and is relatively thin.

It heats up when current passes through it. Naturally, this heat also affects the short leg 43, but this effect is only noticeable in the higher power levels, because the spring does not otherwise rise much above the room temperature. Thereby, however, one compensates for the negative effect of the degressive deflection with temperature, or one counteracts

does this negative factor.

In contrast, the compensation bimetal is largely shielded from the temperature. It runs perpendicular to the working bimetal and has no conductive connection with it. The intermediate wall 42 also provides good shielding against the warm room. Against the temperature provided by the snap spring, the compensation bimetal is protected by means of the switch carrier 29. This arrangement therefore ensures that the compensation bimetal can really do what it is supposed to, namely compensate for different ambient temperatures, and it must not work in a compared with the results significantly higher temperature.

The working bimetal and the compensating bimetal/ snap switch unit occupy two sides of the housing, so that one corner is completely free for the switch 50-56. The arrangement of this dimensionally small switch in the same radial plane as the other parts of the power control apparatus enables a strong reduction of the construction dimensions. The depth in the direction of the setting axis can, for example, be less than 25 mm, so that installation with a vertical axis is also possible in very low cooking appliances.

The diode 62 means a positive influence on the function of the power control device. The medium power range rarely presents difficulties for such control devices. The real difficulty lies in the upper and above all in the lower power range. However, with today's hobs, which have relatively high power, it is precisely the lower power range that is critical, when you only want a weak heating of the hob. One must then be able to enable the addition of effects of up to 5% of the total effect and also less (100W for a 2000 W hob). However, this requires very high effects on the bimetal, because this must be able to react very quickly. However, these high effects will not only lead to a strong heating of the device in the higher power range, and use corresponding energy, but will also

raise the temperature of the bimetal to the same extent. This problem can be solved in a simple way by the advantageous lossless and thus lossless heat-free downregulation of the bimetal heating effect by means of the diode. The high power for which the bimetallic heating is designed is not a disadvantage, because it is only used in the lower power range and in this power range the relative in-

switching times are very short. The heating of the control device from the heating device 39 is therefore very small. Conversely, in the high power range, the power will be limited by the diode, so that the heating is also kept within acceptable limits even with the relatively long switch-on times occurring in the high power range.

A further advantage is that you can carry out the heating 39 on

a simple way. If you wanted to make the effect smaller, you would encounter difficulties, because in that case the resistance wires would have to be made very thin in order to achieve small effects at mains voltage, and especially at higher mains voltages, and operational safety would also suffer from this.

Claims (17)

1. Power control device for the controllable supply of electrical power in power pulses to a consumer, with a heated depending on the connected power, pivotably stored bimetallic element which acts on a snap switch over an angularly projecting arm, and with a compensating bimetal, and a cam disc which is rotatable by means of a setting shaft, characterized in that the snap-on switch (27) is pivotally stored as a unit together with the switch carrier (29) and the compensating bimetal (26) fixed on one side and essentially parallel to the snap-on switch (27) on the switch carrier (29), as the cam disc (19) acts on the free end of the compensating bimetal (26) to swing this unit, while the essentially L-shaped bimetallic element (36) is pivotable independently of the pivotable snap switch/compensating bimetal unit. 2. Apparatus according to claim 1, characterized in that the longest bimetallic leg (38) of the bimetallic element (36) is provided with a heater (39) and is possibly supported against the housing (12) by means of an adjustment screw (40) under spring force (41). 3. Apparatus according to claim 2, characterized in that the shorter bimetallic leg (43) runs parallel to the snap spring (30) in the snap switch (27), and by which spring current supply (35) to the switch contact (31) takes place. 4. Apparatus according to one of the preceding claims, characterized in that the heating (39) of the bimetal (36) is connected in parallel with the consumer (70). 5. Apparatus according to one of the preceding claims, characterized in that the adjustment of the snap spring (30) takes place by means of a screw (33) which forms a non-contact repulsion for the snap spring (30), the screw having an incision for controlling the snap spring (30) ). 6. Apparatus according to one of claims 2-5, characterized in that the heated bimetallic leg (38) is located in a heat-shielded, optionally ventilated room (71) that is at least partially in relation to the compensation metal (26) and the snap switch (27). 7. Apparatus according to one of the preceding claims, characterized in that the pivot axis (28, 37) of the snap switch (27) and the bimetallic element (36) with their ends are stored in one of two collapsible housing parts (12, 13). 8. Apparatus according to claim 7, characterized in that one of the housing parts (12) has a recess (25) which accommodates the main elements of the control device, while the other housing part (13) is designed as a lid for the first housing part. 9. Apparatus according to one of the preceding claims, characterized in that a mechanical switch (50-56) for mains disconnection and/or signal contact provision is arranged in the same plane lying across the setting shaft as the snap switch (27) and the bimetallic element (36) . 10. Apparatus according to claim 9, characterized in that the mechanical switch includes a pusher (50) operable by a cam (20) connected to the cam (19) with transversely extending contact arms (52, 5 3). 11. Apparatus according to claim 10, characterized in that the pusher (50) lies diagonally in a corner of the right-angled, preferably square housing (12, 13). 12. Apparatus according to claim 10 or 11, characterized in that the pusher (50) consisting of insulating material has at least four guides made of metal running across the pusher (55), which guides lie opposite each other in pairs and carry fixed the contacts (56), respectively form these, and protrude through the housing (12) to form connection tabs (57). 13. Apparatus according to one of the preceding claims, and powered by alternating current, characterized by a diode (62) which, by means of a switch (61) operable with the setting shaft, is switched on in front of the heating of the bimetal (39) in the upper power range, and is switched off in the lower power range. 14. Apparatus according to claim 13, characterized in that the diode (62) in the lower power range is short-circuited with the switch (61). 15. Apparatus according to claim 13 or 14, characterized in that the diode (6 2) is arranged on the back of the housing (12, 13), directly at the diode short-circuiting switch (61). 16. Apparatus according to one of the preceding claims, characterized in that the control body (18) which carries the cam disc (19) has a bearing pin (21) which is guided in an opening (24) in the rear of the housing part (12), and in that the setting shaft (15) protrudes into the rearwardly closed central hole (23) in the steering body (18) and forms the second bearing for the steering body. 17. Apparatus according to claim 16, characterized in that the control body (18) carries a cam (22) on its bearing pin for operating the diode (21).