DE1665788C3 - Pressure sensitive circuitry - Google Patents

Description

Fig. 2 a longitudinal section through the pressure sensitive Schaliungsunordiiurm according to Fig. I, but around ■) (! 'Throws,

F i g. 3 is a cross-section along line 3-3 of FIG F i g. I with the anchor arrangement,

F i g. 4 shows a cross section essentially along line 4-4 in FIG. 2 with part of the movable Anchor arrangement and

F i g. 5 is a schematic representation of a control circuit called the pressure sensitive circuit arrangement is used.

The in the drawings and in particular in F i g. 1 and 2 shown pressure-sensitive sound arrangement 10 has a substantially cylindrical housing part 11 and a closure 12, in one end of the cylindrical housing part

11 can be used. The circuit arrangement Hi can be inserted into a housing 13, which is only partially shown in F i 2. \ and which forms part of the housing of a drive with an invariable speed. The housing 13 has a shoulder 14.

A coil 16 is fastened in the housing part 11 and connected to an alternating current source by lines 18. An armature I ¹ J is connected to a piston 70 of an actuating arrangement 20, which responds to the pressure medium in a chamber 21, which is formed by the extension 14, in order to move the armature 19 into one of its bistable positions for changing the impedance of the coil 16 to move, creating either a low impedance or a high impedance of the coil. The chamber 21 is hydraulically connected to the hydraulic control within the drive housing so that the hydraulic pressure medium is fed to the chamber 21.

If there is a pressure above a certain value in the chamber 21, the piston moves 70 to the left, whereby the movable armature 19 is also moved to the left, so that the air gap 22 closed and the impedance of the coil 16 increased to a relatively high value will. On the other hand, if the pressure in the chamber 21 falls below the certain value, moves the piston 70 moves to the right under the action of a helical spring 90, whereby the "armature 19 of the coil is moved away, and a relatively large air gap 22 is created, the impedance lowered in the coil 16 and thus creates a second stable state.

The housing part 11 has protruding lugs 25 for fastening the circuit arrangement in the desired manner Position in the housing 13. The closure 12 of the housing part 11 is formed by a central bore 27 received in the housing part 11. An insulating plug inserted into a central opening in the closure 12 holds the electrical lines 18 in their position. The shutter 12 has forked projections 29 and 30, which are best shown in FIG. 3 can be seen and which extend to a shoulder 32 in the Bore 27 extend and bear against this. The forked projections 29 and 30 flank one magnetically permeable layered core 34 which forms part of the coil formers 16. The closure

12 is held in the housing part 11 by a snap ring 36 which the projections 29 and 30 against the Shoulder 32 holds. To keep the coil 16 in alignment with respect to the armature 19, locating pins are provided 38 provided.

The variable inductance device 16 is formed by a winding 40 and a substantially U-shaped layered magnetically permeable portion 34. The part 34 is seated with eni-er .. fit in a MittelöiTnung in the winding 40 and has Schcnkelteile 42 and 43, 44 define the ends of a portion of the air gap 22nd

The armature 19 has a substantially U-shaped core 50 which can be made from laminated ferromagnetic plates similar to the core 34. A generally U-shaped retaining element 52 surrounds and is attached to the layered core. The anchor 19 surrounds a shaft 54 which extends through the holding element and the anchor 50. The shaft 54 carries a permanent magnet 56. The core 50. the holding element 52 and the permanent magnet 56 are; ^i- 'f the shaft 54 held by an enlarged part 57 at the front end of the shaft 54, which is used to

at gneien 56 to load against a shoulder 58 on the shaft 54. In its central part, the housing part 11 has a partition 60 with a substantially rectangular one Slot 61 for receiving the retaining element 52 in a sliding manner.

The actuation arrangement 20 serves to pull the layered core 50 out of its position in FIG. 1 and 2 shown Position, which is referred to as the first position, to move into a position in which he is stratified Core 42 rests and which can be referred to as the second position. The participation order 20 has a stepped, substantially cylindrical KoI-, contact 65, the in the right end of the Gchäusjteils Il sits and is held in this by a ring 67. A central bore 68 in the piston guide 65 is used for the sliding reception of the piston 70, which is at one end with a widened Head part 71 is formed. In the right end position of the piston 70, the head part 71 rests on an annular one Housing shoulder 72.

The right end of the piston 70 is exposed to the pressure medium in the chamber 21. A closed one Axial bore 75 is provided centrally in piston 70 for receiving the extended end of shaft 54.

Between the piston 70 and the armature 19, a lost motion connection 76 is provided to the adjust the armature exerted by the actuator 20 closing force. In particular, the Totjang connection has 76 a pin 77 which is located within the diametrical bores in the head part 71 of the piston 70 is fixed and extends through a longitudinal slot 79 in the shaft 54. One within the Axially bore seated compression spring 80 normally loads the shaft 54 from the piston 70 to the outside zn a position in which the pin 77 on the right End of slot 79 as shown in FIG. 2, is applied, whereby a further extension of the shaft 54 from the axial bore 75 is prevented; as can be seen from the following, the spring 80 is used for this purpose.

the desired closing force between the anchor 50 and the fixed core 34 regardless of the To generate force of the hydraulic pressure acting on the piston 70.

The actuator assembly also has a screw

f> 5 bcnfedcr90, which is against a shoulder 91 is supported in the housing part 11 in order to retract the piston 70 to the right into its!. · or first position to charge. The spring 90 is also supported against a

Essentially cup-shaped Fcdersitzclcment 93 with a flange 94 from which a seat for the a linden tree of the spring 90 forms. The Fcdcrsitzelcmcnt 93 white! a MittelclölTnung 94, which the shaft 54 freely records. The spring 90 therefore loads the piston 70 into its retracted position the l'cdcrsitzclcment 93. The spring 90 is with reference on the area of the beiasictcn by the pressure medium Side of the Knibens 70 chosen so that at a certain pressure, for. B. of 7 kg / cm'- ', in the Chamber 21 of the piston 70 is moved to the left against the force of the spring 90, whereby the gap 22 is closed; If the pressure then falls below the certain value, the spring 90 loads the Piston 70 to the right, whereby the gap 22 is opened.

The spring felt element 93 has projections 95 which flank the sides of the armature holding element 52 and serve to limit the movement of the piston 70 to the left. When the piston 70 moved to the left and takes the Haltcelcmcnt93 with it, the projections 95 come at the end of a depression 97 in the housing part 11 to the plant, whereby a further movement of the piston 70 is prevented. The limits of movement of the piston 70, the through the shoulder 97 and the housing shoulder 72 are formed are chosen so that the piston 70 '-ich from its in F i g. I and 2 position shown moved into its second position, in which the projections 95 on the shoulder 97 after a larger one Away / ur attachment come as is necessary. about a contact: between the armature 50 and the core 42 bring about. The piston 70 therefore has a larger I.Vrc Movement than the armature 19 from.

in the housing parts 11 and 14 are drainage channels 102 and 1Q3 provided for draining leakage fluid. The liquid draining from the channel 102 flows to a liquid container within the housing 13. To avoid the leakage of Liquid from the chamber 21 is an annular seal 105. To prevent the leakage of liquid from the Avoiding the housing 13 between the housing part 11 and the inside of the projection 14 is one further ring seal 106 is provided within a suitable annular recess in the circumference of the housing part 11 is seated.

The aforementioned permanent magnet 56 serves to attract magnetic particles floating in the pressure medium collect which leaks past the piston 70 from the chamber 21. This prevents that Collect foreign particles in the air gap 22 and interfere with the operation of the switch.

If during operation of the chamber 21 below r> is a certain value, the preloaded spring 90 holds the piston 70 and the armature 19 in the in F i g. I and 2 position shown. The existing large air gap 22 in the magnetic Circle means that the reel ticket vidcr stand

ίο is low and a considerable current flows through a load resistor R ₁ , as in the control circuit in FIG. 5 shown. A control or display device 100 is connected in parallel to the load resistance R _1. During this operating state, the current / ;, is largely determined by the value of the load resistance R, _ . This state can be selected as either the "on" or the "off" state.

When the pressure in the chamber 21 exceeds the specified value, the piston 70 moves to the left against the loading force of the compression spring 90. Before the projections 95 come to rest on the shoulder 97 in the housing part 11, the armature 50 comes to the ends of the legs of the core 34 in the fixed coil 16 to the plant. However, the hydraulic pressure acting on the piston 70 continues, whereby the actuator assembly 20 is moved to the left until the projections 95 come to bear on the shoulder 97. During this movement, the pin 77 leaves the right end of the longitudinal slot 79 in the shaft 54 and assumes a floating position therein. When the armature 50 comes to rest on the core 34, the closing force between them is therefore determined by the compression spring 80 which acts against the rear end of the shaft 54, and can be selected in the desired manner. The impedance of the coil 16 is then large compared to the load resistance R ₁ , since the air gap 22 is very small and the current /, is very small, since it is essentially determined by the reactance of the coil. The low value of the current flowing through the load resistor R ₁ changes the bistable state of the display or control device 100.

When the pressure in the chamber 21 drops below the certain value, the spring 90 leads to the actuator in the first retracted position, in which the return of the armature to the in F i g. 1 and 2 position shown takes place.

1 sheet of drawings

Claims (6)

I 665 788 patent claims: 1. Pressure-sensitive circuit arrangement with a coil arrangement with variable inductance and a pressure-sensitive device for changing the value of the inductance, soft is connected to a magnetically permeable armature opposite the coil assembly is movable, and the armature below a predetermined pressure value against 'a core of the coil arrangement by the action a spring is held at a certain distance, characterized in that that the pressure-sensitive device consists of a piston (70) connected to the armature (19j) exists, which is displaceable against the action of a helical spring (W)). around the anchor (19) to bring with the core (34) at a predetermined pressure substantially in abutment, so that the Impedance of the circuit arrangement at the predetermined pressure value is between a high and low value changes. 2. Circuit arrangement iiach claim 1, characterized by a dead joint (76) which connects the piston (70) and the armature (19) and allows an extended piston path, with a Γ; the (80), which the armature (19) from The piston (70) pushes away and which determines the closing force acting on the armature (19). 3. Circuit arrangement ns -h claim! Or 2, characterized by means (56) for collecting metal particles contained in the from the Fluid escaping from the pressure chamber are carried along. 4. Circuit arrangement according to claim 3, characterized in that the collecting device is formed by a permanent magnet (56) next to the piston (70) and between the piston (70) and coil arrangement (19) lies. 5. Circuit arrangement according to claim 2. 3 or 4, characterized in that the piston (70) has an enlarged head part (71) which in a piston position on a Gehiiuseschultcr (72) rests, and that the piston also has an axial bore (75) for receiving one on the armature attached shaft (54) which slides in the axial bore, and the spring assembly between piston (70) and armature (50) from a compression spring (80) fitted in the axial bore consists, which seeks to push the shaft out of the axial bore, the lost motion connection (76) between the armature and the shaft consists of a longitudinal slot (79) with a pin (77). 6. Circuit arrangement according to claim 5, characterized by a spring seat element (93), which rests on the enlarged head part (71) of the piston (70), with one arranged in the housing, helical spring (90) in contact with the spring seat element and with the spring seat element arranged fork-like projections (95), through which the piston in its other Position is limited and which extend axially on the sides of the armature (50). The invention relates to a pressure-sensitive circuit arrangement having a coil arrangement variable inductance and a pressure sensitive device for changing the value of the Inductance, which is connected to a magnetically permeable armature opposite the coil arrangement is movable, and the armature is below a predetermined pressure value with respect to a core the coil assembly by the action of a spring ^{lü is kept} at a certain distance. Such pressure-sensitive circuit arrangements are used as measuring devices for pressure measurement a continuous measuring range is used (manual for electrical measurement of mechanical quantities, 1967, VDI-Verlag GmbH, Düsseldorf, page 539). Pressure sensitive switches are also used for fixed speed drives in aircraft used to indicate when the hydraulic delivery pressure for certain hydraulic controls has reached a permissible high value, and also to indicate that the output speed is in a permissible range so that the drive delivers the required power to the shaft of a The synchronous generator coupled to the drive provides the electrical energy supply for the aircraft forms. They existed for this purpose used switch from a switch mechanism, the electrical alternating contacts in bistabilcr Arrangement and having a hydraulically operated piston which is responsive to the hydraulic pressure and actuates the switch mechanism at a certain pressure. By using this switch serious disadvantages have arisen in that they are relatively short-lived in some applications and would be unreliable due to the strong current flowing through the contacts and the vibrations in the environment, and since the temperature and pressure fluctuations are proportionate short contact life. The present invention is based on the object to provide bistable pressure sensitive circuitry similar to those previously described Avoids disadvantages of the previously known pressure-sensitive switches, and which as küiiiaktioser switch can work. This is achieved according to the invention in that the pressure-sensitive device consists of a piston connected to the armature, which against the action of a helical spring is vcischiebbar to the anchor with the core at a given Bring pressure essentially in Appendix 2:11, so that the impedance of the circuit arrangement at the given pressure value is between a high and a low value changes. The invention provides a pressure-sensitive circuit arrangement which either has a supplies a high or a low current value, in contrast to the Bckennen working with strain gauges Arrangements which result in a pressure-sensitive analog operating circuit arrangement, such as they are described, for example, in the "Archive for technical measuring", delivery 274 of November 1958, page 226 are. The invention is explained using an exemplary embodiment shown in the figures; it shows F i g. I a longitudinal section through the pressure-sensitive circuit arrangement,