HU187035B - Process for production of liofilated absorbed combined vaccines - Google Patents

Abstract

The invention relates to a pressure switch which is provided with a membrane-piston sensor and whose switching hysteresis can be adjusted by means of an external hysteresis adjusting element (17). The pressure switch according to the invention contains a membrane (2), which moves on the influence of pressure against a helical spring which is variably prestressed, a piston (3) and a piston rod (4), which operates an electrical quick-break switch, which is designed in a bistable manner, with the aid of two coupling discs (6, 7) and an arm (9). One of the coupling discs has a variable-height switching edge; the separation of the contact points between the discs and the arm, and hence also the switching hysteresis, can be varied by rotating it. The rotation of the external hysteresis adjusting element in the housing (11) is transmitted to the coupling discs via a driver element (18). <IMAGE>

Description

BACKGROUND OF THE INVENTION The present invention relates to a diaphragm piston pressure switch with an adjustable switching hysteresis (recoil differential) in which the pressurized chamber is closed by a gas-tight elastic flat membrane and the piston and piston rod Depending on the actuator, it moves it with the switch discs in operative engagement with the piston rod, which actuate an electric momentary switch via a pretensioned lever.

Diaphragm-piston pressure switches which do not have a hysteresis adjustment are known (for example, described in West German Patent No. 1,940,338) and therefore have limited system application. Usually they are suitable only for limit switching and cannot be used as a two-position controller where both the lower and the upper switching point - preferably independent adjustment - are required. Otherwise, the control function can only be achieved with two separate pressure switches.

Also known are diaphragm piston pressure switches having hysteresis adjustment capability (see, for example, the appropriate pressure switch types of SOR / BETA or R. SCHEUFFELE, and the switching hysteresis / microswitch) by adjusting the distance of the contact, i.e. however, the adjustment mode adversely affects the electrical load and electrical life information of the electrical snap-action switch. Excessive removal of contacts will result in loss of the reset function, but excessive proximity may cause the sensor to burn, even at low electrical loads. As a result, the scope of the claim is severely limited and in most cases, the user cannot be trusted.

It is an object of the present invention to provide a pressure switch incorporating the advantages of a diaphragm piston sensor (high overload, vibration resistance, high mechanical lifetime) while providing electrical switch guarantee load and lifetime data and a wide range of adjustable hysteresis at low cost . The hysteresis statement must be solved from the outside without opening the housing and providing access to the pressure switch interior, since opening the housing involves an increase in size and complexity (since space must be provided for the hand or adjuster, removable cover must be provided) , and when the hysteresis actuator and the electrical switch are placed in the same space, the hysteresis adjustment can only be performed after the device has been de-energized for safety reasons (see, for example, RT pressure switches from DANFOSS). It is desirable to ensure that the setting of the switching points is independent of each other. A solution must be found to overcome the main obstacle to the hysteresis adjustment of the diaphragm piston pressure switches, i.e. to increase the small movement range (stroke) of the diaphragm and piston. The structure is small, universal, quick and easy to adjust,

The achievement of the set objective was based on the resurrection that the distance of the switching discs can be varied by rotating from the outside via a driving element. The switch edges of the discs operate an electric momentary switch made bistable by an external arm. Increasing the distance between the points of contact between the discs and the lever will increase the hysteresis and decrease the amount of spring force required to fill the on / off path. . Preferably, one of the coupling edges rises axially, e.g. helical, and the other lying in a plane perpendicular to the axis. The axially variable height switch edge allows the point of contact of the lever and the switch disk to be displaced locally - i.e., rotated about its own axis at a constant axial height. The other of its constant height ensures that the switching point it determines remains in place. The screw for adjusting the switching pressure rotates with the hysteresis actuator so that the prestress of the screw spring is unchanged when the hysteresis is adjusted.

To meet the requirement of versatility, the diaphragm is secured with a separate insert pressed into the housing, which material can be selected according to the particular operating medium, so in case of aggressive media it is sufficient to replace the low-material parts (insert ♦ diaphragm) . Increasing the stroke of the sensor flat membrane was made possible by a conical burst of the contact surface of the housing above the membrane, so that the membrane could be deflected in both directions from its original unloaded plane without increasing the degree of deformation due to displacement. This solution also has the advantage that at low switching pressures, the watering surface of the sensor in the exposed surface (not supported by the piston) of the sensor is golden increased, with the hysteresis adjuster at a given fixed position lower than at high switching pressures, where the pressure deforms the membrane into the conical eruption, thereby reducing the effective surface area and consequently increasing the hysteresis. Thus, at low switching pressures and low set hysteresis values, the pressure switch acts as a more sensitive loose diaphragm switch and is only converted to a diaphragm piston switch once the free surface of the diaphragm is gradually raised. This positive effect, together with the change of friction, superimposed upon the automatic switching depending on the set switching pressure, multiplies the range of the hysteresis adjustment. This increases the ratio of the maximum and minimum switching pressure that can be set on the pressure switch and can still be used up to their system technology, the so-called grip. This is also served by our solution whereby the force of the screw spring is transmitted to the diaphragm through a sphere-fitting ball, whereby the slant of the screw spring does not create a frictional force between the piston rod and the housing with little bias, hysteresis at low switching pressures.

The invention is exemplified! Embodiments thereof are illustrated in the accompanying drawings. Although the figures are referenced in the relevant places, they are also summarized below:

Fig. 1 is a longitudinal sectional view of the pressure switch of the present invention, respectively

187,035 views.

Fig. 2 Λ a piston rod and another possible embodiment of the switching discs.

Figure 3 Detail of the electrical switch housing illustrating the installation of the lever and rotary spring.

It is the fake medium. It is inserted into the chamber 1 (Fig. 1), and by pressing the diaphragm 2, the piston 3 and the piston rod 4 against the screw spring 5, press the discs 6 and 7, which with the rotating nigger 8 as shown in Figs. they operate the electric momentary switch 10 by tilting the pre-tensioned lever 9. The diaphragm 2 secures the insert 12 in the housing 11. The membrane 2 also serves as a seal so that only two parts of the mold are in contact with the medium. Under the 2 memrane load, it rests in a conical chamfer 13 formed in the housing 11. The range of movement of the moving elements is symmetrical with respect to the wiping plane 14. The distance between the contact points 15 and 16 of the switch edges on the switch discs 6 and 7 can be rotated by rotating the switch discs 6 and 7, preferably in the form of a disc, which is rigidly coupled to the outer hysteresis adjuster 17 18 driving elements. The lower contact point 16 of the switch edge, which is firmly connected to the piston rod 6 or, as shown in Fig. 2, on the piston rod 4 and pivoting therewith, is axially variable. The lever 9 is supported by the shaft 19 in the electrical switch housing 20 (see Figures 1 and 3), preferably with a snap fit. The rotary spring 8 applied to the shaft 19 permanently presses the end of the lever 9 on the actuator element 21 of the electric blinker 10 with a force less than the minimum switching force but greater than the maximum switching power, so that switch 10 is bistable. The force between the diaphragm A2 and the screw spring 5 is transmitted by the ball 22, either secured to the upper switch disc 7 or to the end of the piston rod 4 (see FIG. 1 and FIG. 2), which fits into the spherical seat 23 in the lower spring plate. The upper spring plate 25, which is adjustable by means of the adjusting screw 24, is aligned with the drive element 18. The flattened hysteresis adjusting member 17 is secured by a frictional force generated on the securing ring 27 by prestressing the shell 26. The sealing ring 28 serves for sealing. In addition to the gasket, the O-ring 29 also serves to frictionally secure the adjusting screw 24. Of course, the two adjusting elements (17 and 24, respectively, for fastening in the Tube 11 and the hysteresis adjusting element 17) can also be screwed in another embodiment. If necessary, the adjusting elements can be covered by a plastic cap which snaps into the housing 11. The hysteresis actuator 17 is used to collide at two end positions, the two end positions being defined by the minimum and maximum distances between the contact points 15 and 16 on the switching discs 6 and 7. The minimum distance is greater than the lever arm 9 and the maximum distance is shall be less than the sum of the thickness d of the lever 9 and the lever s shall be determined by the lower point of impact of the collision surface (Figures 1 and 2) on the upper piston 3 and the upper switch 6 or on the piston rod 4. The hysteresis adjuster 17 position of the element between the two end positions on the information scale 31 can be read.

The pressure switch of the present invention operates as follows:

In the initial state, i.e. without inlet pressure, the assembly of the piston 3, the pistons 4 and the switching discs 6 and 7 is pressed by the prestressed screw spring 5 and the upper switching disc 6 is pushed through the lever 9 by the actuator element 21 holds. When the chamber 1 is subjected to a pressure such that the force exerted on the diaphragm 2 overcomes the force of the coil spring 5, the piston 3 starts upwardly, and when the lever of the lower switch dial 7 reaches and presses the lever 9, The electric momentary switch 10 remains in this switching position until the edge of the switch switch 6 of the top switch 6 is moved back down due to the pressure drop. When overloaded, the piston 3 collides with the housing 11 and the diaphragm 2 engages in a tapered break 13. The lower switching pressure values are also achieved by wrenching the outer hysteresis actuator 17 with a wrench.

It will be apparent from the description that the pressure switch described in the exemplary embodiment fulfills the intended purpose, which results in the creation of a universal device that is easy to adjust and manufacture, and is small in size.

Claims (11)

Patent claims 1. A diaphragm piston pressure switch with an adjustable switching hysteresis having an elastic flat membrane that seals the gas chamber under pressure, a piston and a piston rod that can be displaced axially by a force acting on the diaphragm, and a pivotable actuator having an opposite force; and an electrical instantaneous switch operated by a pre-tensioned arm connected thereto, characterized in that it has two switching discs (6 and 7), at least one of which is in forced engagement with an external hysteresis pivotally arranged in the housing (11) with adjusting element (17). The diaphragm piston pressure switch according to claim 1, characterized in that there is at least one switch disc (6 and / or 7) pivotally disposed about the axis of the piston rod (4) relative to the lever (9). The diaphragm piston pressure switch according to claim 1 or 2, characterized in that at least one of the switching discs (6 and 7) has a switching disc (15 and / or 16) at the point of contact with the lever (9). hc ^{! ! ,} n has an axially variable position. The diaphragm piston pressure switch according to claim 1, characterized in that, depending on the chemical aggressiveness of the actuating medium, it has a changeable material (12) firmly fixed in the housing (11). The diaphragm piston pressure switch according to claim 1 or 4, characterized in that the housing (11) has a conical chamfer (13) above the diaphragm (2). 6. A diaphragm piston pressure switch according to claim 1, characterized in that the screw spring (5) is provided with a spherical seat. The lower spring plate (23) 187.035 and the assembly of the piston rod (4) and the switching discs (6 and 7) are connected via a ball (22). The diaphragm piston pressure switch according to claim 1 or 6, characterized in that it comprises a lower switch disc (7) fixed on the upper switch disc (6). The diaphragm piston pressure switch according to claim 1 or 6, characterized in that it has a piston rod (4) directly connected to the ball (22) and both switching discs (6 and 7). The diaphragm piston pressure switch according to claim 1, characterized in that it has an upper spring plate (25) which is secured against rotation due to the forced engagement with the drive element (18). The diaphragm piston pressure switch according to claim 1 or 9, characterized in that it comprises a screw spring (5) and an adjusting screw (24) pivoting together with the external hysteresis adjusting element (17). The diaphragm piston pressure switch according to claim 1, characterized in that the electrical switch housing (2) has a bearing arm (9) which is constant due to the torque of a rotary spring (8) applied to the shaft (19). is in contact with the actuator of the electric momentary switch (10)