NO138159B - HEAT INSULATING COATING. - Google Patents

Description

Pressure-sensitive device.

The present invention relates to a

device which is sensitive to the pressure in pressure media and which can be used to influence other mechanisms, e.g. a switch e. 1., as the device has a flexible disc or membrane which is exposed to the pressure in the pressure medium.

Pressure-sensitive devices have long

have been used to move switches e. 1. mechanisms, but such devices have so far had certain shortcomings. A shortcoming has been that the disc member or diaphragm, although made of metal, has been prone to rupture during use, as the diaphragm was necessarily thin to ensure the necessary flexibility. Another shortcoming of known constructions is that complicated mechanisms are often necessary to amplify the diaphragm movement so that the movement is large enough to be able to perform the desired movement of the switch or another device that is controlled by the diaphragm.

An object of the present invention is to produce an improved pressure-sensitive device which eliminates the shortcomings discussed above.

In accordance with the invention

a pressure-sensitive device is provided for actuation of an electrical switch and it comprises a flexible disk which is mounted in a housing and intended to bend when subjected to the pressure difference between the pressure in the fluid located on the two opposite sides of the disk and the device is characterized in that an actuating member arranged on the disc for the switch comprises a

arm which is structurally made one with the disc and which is directed outwards in relation to this, and that the disc close to its circumference bears against a yielding support device which forms pivot points for the deflection of the disc.

In the drawings that accompany the description and form part of the patent, a number of embodiments that the invention can assume are shown for illustrative purposes, and in these drawings: Fig. 1 is a side elevation, partly in section, of a preferred embodiment of the invention. Fig. 2 a cross-section which generally corresponds to the line 2-2 in fig. 1. Fig. 3 is an enlarged partial cross-section which

generally corresponds to line 3-3 in fig. 1.

Fig. 4 is an enlarged view of a detail. Fig. 5 is an exaggerated, generally schematic view of a detail. Fig. 6 is a cross-section of another embodiment of the invention. Fig. 7 is a generally corresponding cross-section

line 7-7 in fig. 6.

Fig. 8 an enlarged partial cross-section generally corresponding to the line 8-8 in fig. 6, and

fig. 9 is a view similar to fig. 6, but with individual parts set in different regulated relative positions.

In the embodiment shown in fig.

1 and 2, a housing 10 formed of two is shown

housing parts 11 and 12, fastened together by means of suitable screws 13. The opposite surfaces of the housing parts are designed with corresponding recesses, one of which

produces a chamber 14 and the other produces a chamber 15. As shown in the drawing, the chambers are separated by means of a relatively thick metallic diaphragm, or disk 16. This disk in the present embodiment and for purposes of illustration is approximately 10 cm in diameter and approximately 0.3 cm thick.

Each housing part 11, 12 is provided with an annular groove towards the periphery of the disk 16, and O-rings 17, 18 are arranged below the respective grooves for sealing contact with the respective adjoining surfaces of the disk. It will be obvious that the parts are given such dimensions that when the screws 13 are tightened, the disc will be clamped between the O-rings so that the periphery of each chamber 14, 15 is sealed off. As will be seen later, since the periphery of the disc is clamped between elastic and compliant O-rings rather than between the non-flexible housing parts, the disc can warp despite its thickness. This is a consequence of the compliant O-ring allowing a certain degree of movement for the periphery of the disc.

As can best be seen from fig. 1 and 2, have

the disk 16 a structurally connected tongue or arm 19 which extends radially outwards from the periphery of the disk. Each housing part 11, 12 is provided with a notch to let the arm through, such notches allowing the arm to extend from the housing 10 and providing sufficient clearance so that the arm's movement, as will be shown later, is not hindered.

Attached to the housing 10 by means of

head screws 20, is a cover 21 which is open at 22 to pass through the arm 19. In the present embodiment shown, a pair of suitable switches 23, 24 are placed inside the cover 21 at a suitable distance from each other to be actuated by movement of the arm 19. These switches can be used to control the operation of, for example, pumps, warning systems, or other suitable equipment, and each switch has a protruding switch button 25 which moves its internal switch mechanism.

The free end of the arm 19 in the present embodiment is not in direct contact with the switch buttons 25, but instead carries the following mechanism for the purpose to be described. As can best be seen from fig. 3, the free end of the arm 19 is pierced for the passage of an externally threaded pin part 26. The pin 26 is threaded through the middle part of a saddle part 27 and a nut 126 is threaded onto the pin to fix the saddle part 27 and the arm 19 firmly together . The saddle part 27 has thickenings 28 on each side of the arm 19, and these thickenings provide oppositely directed bores for sliding reception of respective plunger pistons 29. Each plunger piston is compliantly pressed in the direction from its bore by means of a spring 30, and each plunger piston has a axially protruding construction cam 31 for purposes to be shown.

Included on the respective ends of the pin 26 are heads 32 having rounded ends 33 to abut against the respective switch buttons 25. The end of each head on the opposite side of the rounded head assembly 33 is provided with a plurality of recesses 34 ( see fig. 4) placed at the same distance from each other and from the axis of the head, and these recesses are placed in such a way as to receive the respective contact lugs 31 on the respective plunger pistons 29.

Since the heads 32 are threaded onto the pin 26, each head can be screwed along the pin to increase or decrease its distance from the arm 19 to thereby cause movement of the switches at different pressures as will be seen later. As the contact lugs 31 are elastically pressed into the recesses 34, they will effectively prevent undesired turning of the heads; as the recesses 34 are not particularly deep in the meantime, the heads can nevertheless be turned to carry out the aforementioned adjustment. During the rotation of a head 32, the contact cam 31, by means of which it is retained, will be pressed by means of its spring 30 into subsequent recesses until the head has been turned to the desired position, after which the contact cam, by being elastically placed in a recess, holds head in a position against unwanted rotation.

As can best be seen from fig. 2, a wall 35 of the cover 21 is removably held in place by means of screws 36 to provide easy access to the interior of the cover.

In the position of the parts shown in fig. 1, and with the assumption that the respective chambers 14, 15 are connected to pressure media under pressure through respective lines 114, 115, the pressures in the chambers 14, 15 are essentially the same whereby the disk 16 will be in the flat, unstressed position as shown. If e.g. the pressure in the chamber 14 is greater than the pressure in the chamber

15, either by an increase in the pressure in the chamber 14 or by a decrease in the pressure in the chamber 15, the disc 16 will be deflected from the position shown by solid lines in fig. 5, and to the bowl-shaped position as shown in dotted line. When the disc 16 is deflected to the position as shown by the dashed line, the part of it which is held firmly by the O-ring 18 will tend to swing about the pivot points formed by such an O-ring. This bending movement in the disc will essentially be unimpeded as the disc is clamped between elastic O-rings instead of between rigid housing surfaces as in many previously known constructions.

When the disk 16 is bent out into the bowl-shaped configuration as shown by the dashed line in fig. 5, the arm 19 will be bent to its position as shown by the dashed line to move one or both of the switches 23, 24. It appears that due to the length of the arm 19, its free end will move over a distance that is several times as great as the distance that the disk itself moves during the deflection. The arm 19 therefore reinforces the movement of the disk and makes the device much more sensitive to small pressure differences in the respective chambers 14, 15. It will be easily understood that when the pressure in the chamber 15 exceeds the pressure in the chamber 14, the disk 16 will be deflected in the opposite direction direction to thereby move the free end of the arm 19 in the opposite direction to that shown in fig. 5.

The embodiment illustrated in fig. 6 to 9, is in many respects similar to the embodiment already shown, and as a result the corresponding parts are given the same reference designations, but with the suffix "a" added. In this embodiment, the housing 10a forms only one chamber 14a on one side of the disc 16a, the other side of the disc facing the atmospheric pressure. As the right side of the disk 16a (in the position shown for the parts) is only exposed to atmospheric pressure, a switch 37 can advantageously be placed next to this side of the disk in order to provide a more compact construction. Furthermore, in this embodiment, since there is only one pressure chamber, only one O-ring 17a is needed to prevent leakage of pressure medium, the disk 16a being clamped between a surface 38 on the housing part 12a and the O-ring 17a which is carried of the house part lia.

In order to provide a stronger degree of compactness, the arm 19a of the disk 16a does not extend radially outward from the disk as in the previously shown embodiment, but instead extends in the direction of the diameter from an edge of the disk inwards (see Figs. 6 and 7) . In this construction, the disk 16a has a short projection 39 which extends radially outwards from the periphery of the disk and one end of the arm 19a is rigidly attached to this projection by means of rivets 40 e. 1. An intermediate disk 41 is preferably placed between the arm and the projection for to separate the arm from the adjacent surface of the disc, and as best shown in fig. 7, the housing part 12a has a recess at 42 to pass through the arm 19a and provide free movement for this arm.

The cover 21a is attached to the housing part 12a by means of suitable screws, and in this embodiment the cover 21a only carries a single switch 37 which has a switch button 137 which can come into contact with the arm 19a. For the purpose to be explained, the switch 37 is adjustably mounted for movement not only to and from the arm 19a, but also for movement in the longitudinal direction of the arm. To produce such movement, the following construction is currently used.

As can best be seen from fig. 6 and 8, the switch 37 is fixed by means of screws 43 to a leg 44 of a U-shaped spring part 45. The other leg 46 of the spring part 45 fits into and can slide along a recess 47 formed in the cover 21a. A clamp 48 holds the leg 46 in the recess 47 and in any position along this. The leg 44 of the spring part 45 has an ear 49 (see fig. 8) which rests against a rod 50, one end of which is provided with a hole for the passage of a pin 51 attached to the cover 21a and carried by this pin and whose other end is provided with a hole for the passage of a screw 52 which is threaded into the cover and is held up by this screw.

The pin 51 has a head 53, and the rod 50 is pressed into contact with the head by

by means of a spiral spring 54 which is carried by this pin. The other end of the rod 50 is pressed into contact with the head of the screw 52 by means of the elasticity of the spring part 45 whose ear or projection 49 rests against the rod. The end of the screw 52

(not just the head) is provided with a slit for

screwdriver, and a nut 55 is threaded onto the screw to lock it against unwanted rotation. As can be seen from fig. 6, the free end of the leg 46 of the spring part 45 has a transversely protruding part 56 through which a screw 57 rotatably arranged in the cover 21a is threaded.

It appears that when the screw 52 is turned in one direction or the other, after first loosening the locking nut 55, the switch 37 will be moved towards or away from the arm 19a

thereby causing movement of the switch by means of the arm at different pressures in the chamber 14a. When the screw 57 is turned, after first loosening the clamp 48, the switch 37 will be moved in the longitudinal direction of the arm 19a to thereby vary the sensitivity of the switch to the pressure change in the chamber 14a by varying the effective length of the arm 19a.

As shown in fig. 9, the switch 37 has been moved from its most sensitive position as shown in fig. 6, to its least sensitive position. It has also been moved away from the arm 19a so that a greater pressure will be required in the chamber 14a before the arm contacts the cam 137 to effect movement of the switch.

The operation of the embodiment shown in fig. 6 to 9, will be clear from the description of the operation of the previously described embodiment. In the present embodiment, the pressure in the chamber 14a (when such pressure exceeds the atmospheric pressure) will bend the disk 16a in the same way as the disk 16. The disk 16a will tend to revolve around the pivot point which appears in the form of the inner edge of the surface 38 on the housing part 12a in the same way as the washer 16 swings about the O-ring 18. When the washer 16a swings to the right (with the shown position of the parts) into a bowl-shaped configuration, the free end of the arm 19a will be moved to the right thereby causing movement of the switch 37. It will be easily understood that the arm 19a reinforces the movement of the disk 16a in the same way as the arm 19 reinforces the movement of the disk 16.

Claims (3)

1. Pressure-sensitive device for actuation of an electrical switch, comprising a flexible disc mounted in a housing and intended to bend when exposed to the pressure difference between the pressure in the fluid located on the disc's two opposite sides, characterized in that a on the disc (16) arranged influencing means for switches comprises an arm (19) which is structurally made one with the disc and which is directed outwards in relation to this, and that the disc close to its circumference bears against a yielding support device (17, 18) which constitutes pivot points for the disc deflection. 2. Device as stated in claim 1, characterized in that the movable arm (19) which extends outwards from the periphery of the disc is rigidly connected to an influence arm (19a) which is directed inwards, diametrically in relation to the disc, from its side edge. 3. Device as stated in claim 1 or 2, characterized in that the yielding support device (17, 18), which in and of itself comprises rings, has at least one such ring that bears against one side of the disc .