DE7910432U1 - Snap-action switching mechanism, especially for temperature regulators in absorber refrigerators - Google Patents

Description

R. 5333
January 29, 1979 Ki / Kö

ROBERT BOSCH GMBH, 7OOO Stuttgart 1

Snap-action mechanism, especially for temperature controllers. AbsorbeE refrigerators

State of the art

The invention is based on a snap-action mechanism according to the preamble of the main claim. It is one of those Snap-action mechanism known, b ~ -i which the leaf- » spring is designed as a so-called "Omega" spring, which in the untensioned state approximately follows a circular line is bent. These leaf springs have the disadvantage that, for a given size, the usable stroke is proportionate is low. The usable stroke is to be understood as the path taken by the point of application of the leaf spring on the shift lever covered when this is from the first switching position, in which the leaf spring has the greatest effective counter-

• β Ο. «« · ■ * «■ · ft. . «

-2- row 5 3 3

force affects the shift lever, is moved into that switching position in which the pivot bearing of the shift lever, the support bearing of the leaf spring and their point of application on the shift lever lie on a common straight line and the leaf spring is no longer able to exert any effective force on the shift lever. These leaf springs, which are curved along a circular line, are characterized in that their apex height is at the 'i'. ^N ■ pressing the two ends of the leaf spring against one another from the unstressed position to the end-stressed position can be increased to less than 1.5 times without the spring being overstrained or destroyed.

Advantages of the invention

The arrangement according to the invention with the characteristic Features of the main claim has the advantage that the usable stroke of the leaf spring is greater than that of a known one "Omega" spring. It is also in the first switch position of the shift lever, the greater the effective force that the leaf spring exerts on the shift lever, whereas in the extended position of the parts, the supporting force exerted on the support bearing of the leaf spring is lower than in

i) a well known "omega" peder.

The measures listed in the subclaims are advantageous developments and improvements of the snap-action mechanism specified in the main claim is possible.

The usable stroke of the leaf spring can be increased noticeably if the middle area is unstressed

• ie β e c

- 3 - R. 53 3

Leaf spring is bent back against the imaginary straight line going through its two ends. Here are preferred between the ends of the leaf spring and its curved back central area arched outwards Transitional sections provided.

The described design of the leaf spring and the resulting increase in the usable stroke is particularly advantageous for controllers for absorber refrigerators whose refrigeration unit is optionally available with gas or with electrical energy is operable. In this case, there is a simple and concise implementation, if both the closing member of a gas valve and the movable contact of the electrical energy source controlling switch are hinged to the shift lever.

drawing

An embodiment of the invention is shown in the drawing and explained in more detail in the following description. 1 shows a section through a gas fitting for an absorber refrigerator that can be operated either with gas or with electrical energy, and FIG. 2 shows a diagram of the operation of the regulator in the gas fitting according to FIG Figure 1 shown in the unstressed and stressed state, and Figure ¹ illustrates a known J "Omega" spring also lax and tense. In Figure 5, the force-spring travel diagrams of the leaf springs according to Figures 3 and 4 are shown. Figure 6 shows the course of the force which

5333

the leaf spring of Figure 3 exerts on the shift lever in different switching positions. Figure 7 is one of the FIG. 6 shows a corresponding representation of the relationships as they arise when using a known "omega" spring result.

Description of the embodiment

The fitting according to FIG. 1 has one of two die-cast parts 11 and 12 composite housing, on the underside of which a hood 13 made of plastic is placed. That Housing part 12 has a gas inlet bore 14, from which a channel 15 leads to the conical bore of a plug valve 16 leads. This is provided in a known manner with axial and radial bores and lets the gas in certain Positions from the channel 15 to the input side of an ignition safety valve 17 occur, which of a thermoelectrically excitable magnet 18 is monitored. A channel leads behind the ignition safety valve 17 20 to a filter 21 and from there further into a chamber 22 between the two housing parts 11 and 12. This is connected via a thermostatic control valve 24 to a bore 25 in the housing part 12, one of which is a channel 26 leads to a gas outlet bore 28. Parallel to the control valve 24 a throttle 30 is provided, via which a small amount of gas even when the control valve 24 is closed can flow through the valve. To the gas outlet hole 28, a gas line can be connected to the Burner of the refrigeration unit leads.

The plug valve 16 has a rotatably and displaceably mounted Shift shaft 32, in which a cross bolt 33 is inserted,

5333

which engages in longitudinal slots of a shoulder 34 of the plug valve 16. In this, a plunger 36 is mounted so as to be displaceable in a gas-tight manner, via which the ignition safety valve 17 can be opened by pressing in the switching shaft 32. A ring 38 is also attached to the plug valve 16, the free end face of which is designed as a curved track on which one end of a double-armed lever 40 pivotably mounted at 39 rests. The purpose of this lever is described in more detail below. The cam track of the ring 38 is arranged and designed opposite the radial bores in the plug valve 16 so that in the switching position of the plug valve 16 shown, the gas supply to the ignition safety valve 17 is blocked and the lever 40 is pivoted clockwise into the position shown. In a second switching position, the gas supply to the ignition safety valve 17 is released, but the lever HO continues to be locked in the position shown. In a third switch position, the gas supply is blocked again, but the lever HO is released so that it can be pivoted counterclockwise.

The hood 13 encloses a chamber 42 which contains a small electrical switch 43 and the working element HH of a thermostat, which is connected via a capillary line 45 to a heat sensor which is to be attached to the evaporator of the refrigeration unit. The small electrical switch 43 has two connection contacts HS and 47, which are accessible through openings 48 in the hood and protected against contact by the collar 48 surrounding the openings. Via the contacts 46 and 47, the miniature switch 43 can be switched into the circuit of a contactor, which controls the electrical

- 6 - R. 53 3 3

Controls the energy source of the refrigerator. The miniature switch 43 is designed as an idle switch, the switching contacts of which are opened when a switching plunger 50 is pressed downward via a leaf spring 51 attached to the housing of the miniature switch 43. The lever 40 acts on the free end of the leaf spring 51; in the illustrated position the lever 40 locks the small switch 43 in its open position, so that the electric Energieu \ source of the refrigerator and other switches are ineffective for its control.

The working element 44 of the thermostat is on a Fastened rocker 52, which rests on a bolt 53 and on an anvil 54 which is attached to a stud 55 which is screwed into a cross member 56. Of the Bolts 53 and the cross member 56 are in the side walls the hood 13 anchored. The arrangement could also be made so that the housing part 12 with down protruding side walls is executed, in which the parts 53 and 56 are anchored and between the as Cover formed, the miniature switch 43 carrying plastic part 13 is fitted. Against lateral shifting the rocker 52 is secured by the side walls of the hood 13 or the housing part 12. To secure A fold 57 of the rocker 52 and a spherically arched edge 58 of a bore serve against longitudinal displacement 59, in which the correspondingly designed anvil 54 is mounted.

The working element 44 acts on the control valve 24 and the small switch 43 via a switching lever 60. The shift lever 60 has a bend 6l at one end,

• ·

5333

with which it is mounted in the shape of a blade on one edge of a cross bar 62 with a rectangular cross section. At the other end, an adjusting screw 63 is screwed into the switching lever 60, which acts via a plunger 64 on the closing body 65 of the control valve 24, on which a closing spring 66 engages. The plunger 64 is passed through a membrane 67 in a gas-tight manner , which separates the bore 25 in the housing part 12 from the chamber k2. The membrane 67 is fixed by a cover 68 which is crimped into the housing part 12. Furthermore, the switching lever 60 acts on the miniature switch 43 via a stud screw 70 which is adjustably fastened to the leaf spring 51.

The pivoting range of the shift lever 60 is limited downwards by two axially opposite fixed stops 72 formed on the side walls of the hood 13 or the housing part 12 and upwards by an adjustable stop 73. This is formed on a threaded bolt 7k which is screwed into an adjusting spindle 75 and is fixed therein by a drop of paint 76 or the like. The adjusting spindle 75 for its part is seated in an internal thread 77 of the housing part 12, so that the stop 73 can be axially adjusted by turning the adjusting spindle 75.

At the free end of the shift lever 60 is an engagement point 78 for a leaf spring 80 bent in the shape of a bow formed, which is supported on a stop 81 fixed to the housing. The leaf spring 80 acts on the shift lever 60 a force that seeks to pivot it clockwise, and that of the actuating force of the working element 44

- 8 - R. 53 3 3

counteracts. The arrangement is such that the leaf spring 80 exerts on the holding lever 60 The force is greatest when it rests against the fixed stop 72, and decreases when the shift lever 60 moves against it its upper stop 73 moves.

The controller of the valve shown works as follows:

If the heat-sensitive medium in the working element 44 of the thermostat has cooled accordingly, the leaf spring 80 presses the switching lever 60 against the fixed stop 72 at. In this position of the shift lever 60 that is Valve 24 closed and the small electrical switch 43 opened regardless of the position of the lever 40. When the temperature in the cooling chamber then rises again, the actuating force of the working element 44 is applied increasing moment on the gear lever. If the temperature on the evaporator is an upper Limit value reached, overcomes the actuating force of the working element 44 the force exerted by the leaf spring 80 on the shift lever 60, whereupon the shift lever 60 is moved with a snap into its second switching position in which it rests against the stop 73. In Figure 1 the drawing, the shift lever 60 is drawn in a middle position, which he during his snap movement passes through without stopping. In the second switching position, the valve 24 is pushed open, so that gas to the refrigeration unit can flow and heat it. The mini switch 43 remains blocked in its open position via the lever 40. When the plug cock 16 is in its third Switch position, the upward snapping switching lever 60 would move the miniature switch 43 to its on-

in » *»

• · U -.

- 9 - R. 53 3

let go of position. The opening of the control valve 24, which is also going on, would have no effect, because the plug valve 16 interrupts the gas supply in its third switch position.

In the second switching position of the switching lever 60, the leaf spring 80 only exerts a small effective force the shift lever 60, which, however, also has an effect due to the in this second shift position Force of the closing spring 66 is supported. If, after the now occurring lowering of the cold room temperature and the evaporator temperature has reduced the actuating torque of the working element 44 so far that it is the

[Forces of the leaf spring 80 and the closing spring 66 are not

is able to overcome more, the shift lever snaps back into the lower shift position, in which the valve

f til 24 is closed and the miniature switch 43 is open.

The upper switching position of the shift lever 60 is determined

t the switch-off time of the refrigeration unit and thereby

the lower limit of the temperature at the evaporator and thus the cold room temperature (setpoint). By adjusting the setting spindle 75 can adjust the lower limit of the I evaporator temperature to the desired setpoint | the value corresponding to the cold room temperature is set! will. The upper limit of the evaporator temperature becomes' | determined by the assignment of the working element 44 to the shift lever 60 in its lower switching position. This assignment results from a corresponding pivot position of the rocker 52, which is determined by the stud screw is adjustable. The further down the anvil 54 abp is lowered, the more the working medium must be in

- 10 -

· ■ · · · · • β ■ ■ ■ *

»■» Il

- ίο - R. 5 3 3

■ Heat the working element 44 so that the shift lever 60 is moved out of its lower switch position. The stud screw 55 is designed as an adjusting screw which is no longer accessible from the outside after assembling the valve, so that in use the Fitting results in a constant upper evaporator temperature at which a new work cycle of the refrigeration unit is initiated ("constant on control").

The diagram according to FIG. 2 shows the relationships between the setpoint adjustment s for the cooling chamber temperature to be made by the setting spindle 75 and the switch-on and switch-off temperatures t of the refrigeration unit. According to the invention, the upper evaporator temperature, which cannot be adjusted during use of the gas valve and which is shown in the diagram as line a, is above the temperature of 0 ° C in the entire setpoint setting range, so that the evaporator is defrosted before the start of each work cycle of the refrigeration unit. The dependence of the lower evaporator temperature of \ f the set point adjustment arises als'Linie b represents.

According to FIG. 3, the unstressed leaf spring 80 is so flat that when both ends are pressed together 84 and 85 by the maximum spring deflection f occurring during operation, their apex height b to at least double

ITi a, X X

th value of the vertex height b _{Q of} the unstressed spring increases. This is achieved in that the central region 86 of the leaf spring 80 is curved back against the imaginary straight line 87 passing through its two ends 84 and 85. Between this middle area 86 and the ends 84 and 85, the leaf spring 80 has outwardly curved transition sections 86a, which deflect the middle

- 11 -

R. 5 3 3

Section 86 facilitate when compressing the leaf spring. The ends 84 and 85 are slightly bent in the shape of a hook, so that the leaf spring cannot slip off its stop 81 and the point of application 78 on the shift lever 60. In the unstressed state of the leaf spring, the middle section 86 could also be curved over the straight line 87, so that the apex height b "assumes a negative value. In this case, when installing the leaf spring 80, ensure that the middle section 86 is pressed into the position shown in FIG. 3, in which the apex height b _{Q has} a positive value and a deformation of the leaf spring is only possible as shown in FIG is.

In Figure 4, the leaf spring 80 according to the invention is contrasted with a conventional "omega" spring 88, in which when the two spring ends are compressed by the spring travel f _max, the apex height b only increases by a small value and in which the spring material is not overstressed or destroyed in the extreme case, the height of the apex can be increased by about 1.5 times the value of the unstressed spring.

The positive effects of the design of the leaf spring 80 according to the invention are illustrated in Figures 5 to 7. Figure 5 shows the spring characteristics c and d of the leaf springs 80 and 88. To compress the leaf spring 80 by the amount f, the force P. Compression of the leaf spring 88 by the same amount results in the smaller force P ₃ . The forces P ₁ and Pp are transmitted to the articulation point 78 on the shift lever 60 and to the stop 81 as a supporting force, so that more favorable conditions are achieved when the leaf spring 80 is used

- 12 -

12 - R. 53 3

than when the leaf spring 88 is used.

The result is that the leaf spring 80 has a larger usable stroke than the leaf spring 88. This is demonstrated graphically with the aid of FIGS. There an assignment of the leaf spring 80 or 88 to a pivot lever 60 'is shown, as it corresponds approximately to the conditions in the fitting according to FIG. The useful stroke H _n is understood to be the distance which the articulation point 78 'of the leaf spring 80 or 88 on the pivot lever 60' covers between the stretched position and that angular position of the parts at which the leaf spring has the greatest effective force, ie the greatest torque exerts on the pivot lever. The size of the circumferential force exerted on the pivot lever 60 'corresponds approximately to a counterforce A which must be applied in every angular position of the parts in order to move the parts against the extended position. The total stroke Hp is understood to mean that distance which the articulation point 78 'covers between the extended position and that angular position in which the leaf spring 80 or 88 is completely relaxed. In FIGS. 6 and 7, this angular position is indicated by the thick lines for the leaf springs and the pivot lever.

In the diagrams of FIGS. 6 and 7, the force A is greater than that measured from the extended position of the parts Stroke H plotted, the ordinate with the extended position the parts collapse. In the extended position itself, the force is A = O, because the leaf spring acts on the pivot lever 60 'pushes only in the longitudinal direction. For a number of intermediate positions and for the other end position is the force A through graphic forces

- 13 -

R. 5 3 3 3

decomposition determined. The total force P acting in the straight line going through the two ends of the leaf spring results initially from the amount of compression of the leaf spring in the corresponding position and the spring characteristic curve according to FIG P. and into the force A, which acts at least approximately tangentially over the entire swivel range. The force curve determined in this way goes back from the value O in the extended position of the parts via a maximum A, in an intermediate position to the value O in the other end position of the parts. A comparison of the two diagrams of Figures 6 and 7 can easily detect ₅ that the useful stroke lying between the extended position and the angular position with the greatest force impact H _N1 of the leaf spring 80 is not insignificant greater than the useful stroke H _N2 of the known leaf spring 88th It can also be seen that the force A ^ is greater than A ₀

³ Imax ^& 2max

is, which represents a further advantage of the leaf spring 80 over the known leaf spring 88.

κ. 53 3 3

January 29, 1979 Ki / Kö

ROBERT BOSCH GMBH, 7OOO Stuttgart 1

Snap-action switchgear, especially for temperature regulators in absorber refrigerators

summary

The invention relates to a snap-action switch mechanism which is particularly suitable for temperature regulators for absorber refrigerators. The snap-action mechanism has an operating element (44) which acts on an actuator via a pivotably mounted switching lever (60). A leaf spring (80) bent in the shape of a bow engages the switching lever (60) in such a way that the switching lever (60) is able to move between two end positions with a snap. The leaf spring (80) should have the largest possible usable stroke. The leaf spring (80) should exert the greatest possible effective force on the shift lever (60) without the support bearing for the leaf spring and its point of application on the shift lever being excessively stressed. This is achieved in that the unstressed leaf spring (80) has such a deviating from a circular line flattened shape that upon compression of its two ends (84, 85) the maximum to the occurring during operation travel (f_ _ev) their peak height (b) at least increases to twice the value of the vertex height (b _Q ) of the unstressed spring. The invention can be used particularly advantageously in temperature regulators of absorber refrigerators, the refrigeration unit of which can be heated either with gas or with electrical energy. A large usable stroke of the snap spring is particularly desirable in these refrigerators.

Claims (4)

R. 53 3 3 29.I.1979 Ki / KÖ ROBERT BOSCH GMBH, 7OOO Stuttgart 1 Expectations 1. Snap-action mechanism, especially for temperature controllers of absorber refrigerators with a working element that is mounted on an actuator via a pivotable Acting shift lever on which a bow-shaped bent leaf spring engages, which is pretensioned in this way and opposite the shift lever is supported that in a first switching position by the support bearing of the leaf spring and its point of attack on the shift lever making an angle with the point of attack 1 point and the pivot bearing of the shift lever going Raden includes and the leaf spring thereby a maximum ■ counterforce to the actuating force of the working element on the Shift lever and that when the shift lever is moved hebeis in the second switch position the point of application of the : Leaf spring on the shift lever against a bearing and through the support bearing of the leaf spring going ί wheel moves and the leaf spring in the second switching position \ ling a lower or no counterforce to the actuating force - 2 - π. 53 33 of the working element exerts on the shift lever, characterized in that the unstressed leaf spring (80) has a flattened shape deviating from a circular line that when its two ends (84, 85) are pressed together ^{by the maximum spring travel occurring during operation ^ max-} * ^{their snow} height (b) increases to at least twice the height of the apex (b _Q ) of the unstressed spring. 2. Snap-action switching mechanism according to claim 1, characterized in that the central region (86) of the untensioned leaf spring (80) is curved back towards the imaginary straight line (87) passing through its two ends (84, 85). 3. Snap switch according to claim 2, characterized in that between the ends (84, 85) of the leaf spring (80) and whose central region (86), which is curved back, is provided with outwardly curved transition sections (86a). 4. Snap switch mechanism for a temperature controller of an absorber refrigerator, whose refrigeration unit can be heated either with gas or with electrical energy, in particular according to one of the preceding claims, characterized in that on the switching lever (60) both the closing member (65) of a gas valve (24) as well as the movable one - 3 - R. 5333 Switching contact (50, 51) of an electrical switch (U3) hinged are.