DE1665332B2 - Pressure-dependent, multi-pole electrical snap-action switch - Google Patents

Description

The invention relates to a pressure-dependent, in particular multi-pole snap-action switch suitable for washing machines, dishwashers oddgL at least one contact spring protruding between the assigned contact pair has that of an organ that can be influenced from the outside via a pressure exerting a pressure Snap spring as well as under the action of an adjustment spring which likewise produces a pressure standing shift lever is controllable

In a switch »of this type as it is known for example from US-PS 32 33 056, the location is the Switching and reset points are each determined by the force of the adjustment spring acting on the switching lever determines the control lever in relation to the organ acting on this lever from the outside, for example a membrane acted upon by water pressure or air pressure. Of the Distance of the switching and reset points from each other however, depends on the one hand on the distance between the contacts and on the other hand on the spring constant dependent on the adjustment spring. The smallest contact distance itself is again due to the permissible one Flashover voltage is determined, the maximum contact distance, on the other hand, is determined by the geometric conditions the switch construction or the switch housing. However, these dimensions of the switch housing also limit the dimensions of the adjustment spring, which again affects its spring constant and Adjustability affects. So should a switch only with a relatively high expenditure of force on the Switching lever acting organ, so a relatively high fluid pressure in a membrane switch or air pressure, an adjustment with a large spring constant is necessary, which on the one hand generates the necessary spring force and on the other hand causes a sufficiently large supporting force. However, this again has the consequence that the minimum distance between switching and downshifting point is correspondingly larger.

These conditions have so far been adapted in such a way that with different switching forces, With a membrane switch so different pressure levels, in the switch different strengths, the Adjustment springs corresponding to the desired values have been installed. However, this could have the disadvantage that the minimum distance between the lowest switching point and reset point with increasing switching force as a result of the necessary larger spring constants, it also becomes larger and larger, cannot be eliminated.

The invention is now based on the object of the spring system of such a switch train that the minimum distance between the lowest switching point and the reset point possible kept small and the maximum distance between the highest switching point and the The switch-back point can still be kept sufficiently large.

According to the invention, this object is achieved in that the on the one hand on the contact spring and on the other hand on the shift lever located opposite the counter bearing Pivot axis of the shift lever are arranged so that

the torque exerted on the gearshift lever by the snap spring is at least substantially Switching range from the adjustment spring to the Shift lever exerted torque is opposite to this caused by the snap spring Torque decreases when swiveling the shift lever , initially closed, and then decrease again after having covered a certain distance. That The increase in the torque is due to the increase in the spring tension which is initially still taking place as well as the enlargement of the lever arm related to the axis of rotation of the shift lever, the subsequent decrease in torque, however, is due to the subsequent relaxation of the snap spring conditional The superposition of this torque caused by the snap spring with the The torque caused by the adjustment spring has the consequence that the resulting torque line in Depending on the shift lever travel, it rises steeply to then after reaching about the in the middle range between the lowest switching point and the highest switching point get lost. However, this means that in the area of the switch-back point and the lowest switch point only a small total torque is necessary. to move the shift lever. In the area of the At the highest switching point, on the other hand, a greater torque is necessary to operate the gearshift lever to grant the same motion. This process, previously only through the use of different Adjustment springs was achieved, can thus be achieved with one and the same spring system, with only the The preload of the adjustment spring must be changed if the switching processes are at different switching points should be carried out. It is also particularly significant that regardless of the preload the adjustment spring still has a small distance between the lowest switching point and the reset point and also a wide range between the lowest switching point and the highest switching point is possible.

To the Justagefeder opposing Wirku i the snap spring in the full switching range are effective to make, it is convenient that the torque applied by the snap spring on the lever is opposed already in the rest position of the contact spring to the torque exerted by the Justagefeder to the shift lever.

In a preferred embodiment of this torque applied by the snap spring is _so pre-geous also opposes the force exerted by the Justagefeder to the shift lever in the downshift torque point of the contact spring. With this design, a counter pressure is _{exerted on the adjustment spring 5S} even at the moment of switching back, so that it is always in safe engagement with the shift lever there is still a sufficient return reserve to return the control lever

A particularly important feature of the invention that is ancillary to the features discussed so far is characterized in that the contact spring at least in the area between its the contact bearing free end and their counter-bearing associated with the snap spring have a special flexural elasticity having. In this context, it is also advantageous if that located on the contact spring, the Snap spring associated counter bearing approximately in the middle of the contact spring between its free end and the pivot axis of which is arranged. This has flexural elasticity associated with the contact spring a temporal shortening of the zero crossing of the contact spring than that caused by the pressure the snap spring caused deflection of the deformation of the contact spring stored spring force again becomes free at the moment when the snap spring is in the area of its unstable position in which its line of action precisely the pivot axis of the contact spring intersects only a small amount or no torque at all and is able to exert a torque on the contact spring. the The spring force released by the relaxation of the contact spring thus supports the swinging through of the Contact spring just in the crucial phase of snapping the contact spring and presses it through the zero position. In this way, however, the switch-back point can in turn be as close as possible to the The zero point.

Another advantage of this flexural elasticity of the contact spring results from the fact that the Deflection and relaxation of the contact spring cause a relative movement between the one at the free end the contact spring arranged contact and the two fixed contacts is achieved what as a result of the associated friction, all contacts are again self-cleaning

Finally, however, is the possibility that the contact spring can bend elastically, as well also the special arrangement of the counter bearing associated with the snap spring an elastic contact of the reached on the contact spring arranged contact on the fixed contacts and thus the otherwise at stiff contact springs, the dreaded bouncing process is reduced to a minimum

Further details of the snap switch according to the invention and its mode of operation are the the following description of an exemplary embodiment shown in the drawing, as well as can be found in the subsequent claims. It shows

F i g. 1 the section of a multi-pole switch,

F i g. 2 one opposite to FIG. 1 offset Section of an adjacent, reversed spring system of the same switch,

F i g. 3 to 5 schematic representations of the Shift lever attacking moments and

F i g. 6 shows the torque characteristic as a function of the shift lever travel.

The one shown in FIG. 1 switch shown is with a with 1 designated membrane equipped on the pressure of a through a nozzle 2 in the switch interior penetrating liquid or gas responds and arranged on their on the diaphragm plate 3 The plunger 4 acts in a known manner on a shift lever 5 clamped on one side. This shift lever 5 is supported again on an adjustment spring 6, the other end of which is adjustable in height in a sleeve 7 of the switch housing 8 screwed bolt 9 rests

The shift lever 5 is also assigned a contact spring, also clamped on one side, denoted by 10, which in a known manner has a recess for swinging the shift lever 5 and whose free end 12 carrying the contact 11 between the two stationary, but partially

height-adjustable switch contacts 13 and 14 protrudes. This contact spring 10 consists of a relatively elastic leaf spring, which extends from the clamping point 15 to the edge of the recess extending part is reinforced by a downwardly projecting rib 16 so that the remaining part of the Leaf spring is characterized by a special flexural elasticity:

Between the contact spring 10 and the shift lever 5 ″ is an omega spring designed as an omega spring in a known manner Arranged snap spring 17, which is located on the one hand on the protruding nose 18 serving as a counter bearing the rib 16 and on the other hand on the serving as a counter bearing, protruding counter nose 19 of the on the Shift lever 5 arranged lever arm 20 is supported This snap spring 17 is by the of the Membrane 1 controlled from caused pivoting movement of the shift lever 5, which itself again in such a way is cranked at the bottom that its actual pivoting range outside the pivoting range of the contact spring 10 lies and only its lever arm 20 protruding upward through the contact spring 10 swings through the recess.

In Fig.l is the rest position of the switch shown, in which no pressure acts on the membrane and this is thus on a bottom 21 of the Switch cover 22 arranged, the mouth of the nozzle 2 surrounding the annular edge 23 is seated. Corresponding to the membrane 1, the switching lever 5 and the contact spring 10 each take their own Rest positions, in which the adjustment spring 6 pushes the shift lever S against the diaphragm plunger 4 and the Snap spring 17 press the contact spring 10 with its contact 11 against the upper contact 13.

The Fig.2, however, shows one compared to the Fig.l partially offset section of the neighboring Spring system, which is designed as a mirror image of the spring system according to Fig.l and when raised Membrane 1 is in its switched-on position. In addition, the shift lever 5 is this spring system another stop, designated 24, which protrudes into the pivoting range of this shift lever 5, is assigned and its stroke is limited downwards.

The mode of operation of this switch according to the invention results from the two schematic representations in FIGS. 3 and 4.

3 shows the rest position of both the shift lever 5 and the contact spring 10, the contact 11 of which in this case rests on the upper fixed contact 13 the spring force exerted by the snap spring 17 and represented by the arrow 5 in relation to the pivot axis of the switching lever S, indicated by 26. Here, the adjustment spring 6 exerts a pressure on the sound lever 5 in the direction of the arrow /. which at the lever ann a results in a clockwise torque Mi <- a I In addition, the snap spring 17 supported on the two counter bearings 18 and 19 causes a compressive force in the direction of the arrow S, which is the case with the very small lever arm b a counterclockwise torque Ms- b-S causes this torque Ms caused by the snap spring 17, however, with the rest division of the switching system shown in FIG

If, however, a pressure of the adjustment spring 6 acting on the diaphragm 1 is opposed to a pressure force denoted by D and thus the switching lever 5 is raised in the direction of the arrow 27, then

S also causes the counter bearing 19 of the snap spring 17 to move upward duRrh. This movement of the But the counter bearing 19 has the consequence that the line of action determined by the two counter bearings 18 and 19 25 the spring force executes its pivoting movement in the direction of the arrow 28. Here, the line of action 25 passes the pivot axis 29 of the contact spring 10. so that the spring 17 snaps over and the contact spring 10 in Direction of arrow 30 in the FIG. 4 shown The switch-on position presses in that its contact 11 now rests on the lower stationary contact 14

The special relationships of the various acting on the shift lever 5 and the contact spring 10 Moments are in particular also given as FIG. 6 referenced schematic diagram, in which the course of these moments are plotted as a function of the path of the shift lever 5. Of the The path of the shift lever 5 is limited on the one hand by the line 31 and on the other hand by the line 32. In a certain distance from the lower limit

2s line 31 is also drawn the line 33 determining the switch-back point, which must be higher than the lower limit line 31, from there must still be a sufficient reserve between the switch-back point 33 and the rest position determined by the limit line 31. to ensure a safe downshift. Above this switch-back point line 33, the line 34, which determines the lowest switching point, runs parallel. The distance A from the line 31 again depends on the distance between the switch contacts 13 and 14 Limiting line 32 is located The distance B between the two lines 34 and 35 illustrates di <

^, Possibility in which area the desired « Switching point can be arranged.

Furthermore, two dashed straight lines labeled Mi ₁ and Mi are drawn in the diagram. di <the course of the caused by the adjustment spring 6

Represent the moment Mi = a · /. The difference between these two inclined straight lines Mi, and Mi is that in the characteristic Mi ₂ de; Adjustment spring € given a bias and this «characteristic is shifted further to the right

so In the left part of the diagram, dashed and dotted lines show the curve of the moment Afc which results from the product of the force 5 of the snap spring 17 times the lever arm b and is opposite to the two moments Mi _x around Mij With the increasing We)

S _{5 of} the contact spring 10, the value of the moment M initially increases, as when the contact spring 10 snaps through in the direction of the Pfeees 30 de lever arm 6 constantly increases, which ntspred affects the moment Ms

_te half their way back down so now dt relaxation of the snap spring 17, and thus also caused * characterized Redazieraog the spring force S * great that even the further Anwuchsen of the lever arms do not b this reduction in spring force S meh

can compensate.

As has already been stated, the two moments Mi and Ms are superimposed, as a result of which the two i of FIG. 6 solid moment lines (Mi _x + M:

(c,

and (Mi ₂ + Ms) result. These two similar moment lines (Mi ₁ + Ms) and (Mi ₂ + Ms) initially rise very steeply, in order to assume a flatter slope in the middle area. This turning of the moment lines (Mj _t + Ms) and (Mi ₁ + Ms) is caused solely by the course of the moment line Ms.

A comparison, for example, of the torque curve (M /, + ■ Ms) with the torque curve M /, shows that if the shift lever 5 is to cover the distance A , a significantly lower torque is necessary than if only the torque M /, causing Adjustment spring 6 would be present. Since there is a linear relationship between these moments and the counterforce exerted by the diaphragm 1 and thus again the pressure acting on the diaphragm 1, this means that the lowest switching point 34 can be placed very close to the switch-back point 33. In contrast, in order to pivot the shift lever 5 into the highest shift point 33, much greater torques are required.

If the switching points 33, 34 and 35 are to be set higher, the adjustment spring 6 is to be put under tension, whereby the characteristic Mi ₂ and with this of course also the characteristic (Mi ₂ + Ms) is shifted further to the right.

However, the distances A and B between the switch-back point 33 and the lowest switching point 34 or the lowest switching point 34 and the highest switching point 35 are retained, which can also be seen from the following numerical example:

If the switch-back point 33 is in the area of the torque characteristic (Mi _x + Ms), for example at 20 mm WS, the lowest switch point 34 can already be at 50 mm WS, the difference being only 30 mm WS. In contrast, the highest switching point 35 is then 100 mm WS in this case. If the adjustment spring 6 is then given a greater bias, greater shoulder forces are now also required, which also makes correspondingly higher switching pressures necessary, which are now, for example, 120 mm WS, 150 mm WS and 200 mm WS. However, it is essential here that the previously treated pressure differences A and B, in particular the small pressure difference A, between the switch-back point 33 and the lowest switching point 34 are retained even at such high switching points. Due to these circumstances, it is only with the aid of the adjustment spring 6 and the snap spring 17 that it is already done

is possible to set both low and high switching points achieve, with the small pressure difference A between the holdback point 33 and the lowest switching point 34 will continue to exist

Finally, FIG. 5 shows the possibility of applying the switch-back point 33 very close to the zero point even with a large pressure difference. This can be achieved by the fact that the moment Ms caused by the snap spring 17 at the moment when the contact spring 10 snaps over, clearly counteracts the moment Mi caused by the adjustment spring 6 and thus still ensures that the adjustment spring 6 rests properly on the shift lever 5 is when the adjustment spring 6 pushes the shift lever 5 into its rest position

For this purpose 3 sheets of drawings

SBSW

Claims (10)

Patent claims: U Pressure-dependent, multi-pole electrical snap-action switch, especially for iodine washing machines. The like, with at least one contact spring protruding between the associated pair of contacts, which is controllable from an externally influenceable organ via a switching lever which is both under the action of a pressure-exerting snap spring and under the action of a pressure-exerting adjustment spring, characterized in that the support of the snap spring (17) serving on the one hand on the contact spring (10) and on the other hand on the switching lever (5) located counter bearings (18, 19) relative to the pivot axis (26) of the switching lever (S) are arranged so that the through the torque (Ms ) exerted on the switch lever (5) is at least essentially the opposite of the torque (Mi) exerted by the adjustment spring (6) on the switch lever (5). 2. Switch according to claim 1, characterized in that the by the snap spring (17) on the switching lever (S) exerted torque (Ms) already in the rest position of the contact spring (10) that of the adjustment spring (6) on the switching lever (5) exerted torque (Mi) is opposite 3. Switch according to claim 2, characterized in that the torque (Ms ) exerted by the snap spring (17) on the shift lever (5) also at the switch-back point (33) of the contact spring (10) that of the adjustment spring (6) on the shift lever (5) exerted torque (Mi) is opposite 4. Snap switch according to one of claims 1 to 3, characterized in that the snap spring (17) is designed as a helical spring, barrel spring or omega spring 5. Switch according to one of claims 1 to 4, characterized in that the contact spring (10) at least in the area between its contact (It) carrying free end (2) and its der Snap spring (17) associated counter bearing (18) has a particular flexural elasticity 6. Switch according to one of claims 1 to 5, characterized in that the contact spring (10) located, the snap spring (17) associated counter bearing (18) approximately in the middle of the Contact spring (10) is arranged between its free end (12) and its pivot axis (29) 7. Switch according to one of claims 1 to 6, characterized in that the pivoting range of the shift lever (5) is limited by a stop (24). 8. Switch according to one of claims 1 to 7, characterized in that the switching lever (5) is cranked in such a way that its pivoting range outside the pivoting range of the contact spring (10) lies. 9. Switch according to one of claims 1 to 8, characterized in that it is a multi-pole switch is formed and more than one each from a pair of contacts (13, 14), one associated Has contact spring (10) and a switching lever (5) existing switching system. 10. Switch according to claim 9, characterized draws that the adjacent switching systems are reversed to each other.