DE3407827C2 - Diaphragm seal - Google Patents

Abstract

The invention relates to a pressure transmitter for providing an averaged working pressure from the operating pressures of at least two pressure medium sources, with a stepped piston being provided for averaging the operating pressures, the number of step areas of the same size and of the same size corresponding to the number of operating pressures to be averaged, the opposite working area of which is the same the sum of the step areas and which is slidably guided in a correspondingly graduated housing provided with feed lines for the operating pressures, and aims to design the diaphragm seal so that it does not need an additional pressure relief valve for its function within a hydraulic system. This is achieved by providing ring grooves associated with a control edge of the respective step surfaces in the housing and in that discharge lines leading away from the ring grooves are provided which are connected to a common line for the averaged pressure, which in turn is connected to the work surface.

Description

The invention relates to a pressure transmitter as described in the preamble of claim 1 Art.

A diaphragm seal of this type is described and shown in DE-OS 06 573. The known Diaphragm seal has a housing in which a two-stage stepped piston is guided. The graduated piston divides the housing into three work rooms, of which the work rooms assigned to the stepped surfaces are acted upon by the working pressure of a hydraulic pump, while the pressure in the working space which is assigned to the total working area, is used for pressure regulation or control will.

Since the step areas in the same direction are of the same size and the working area in the opposite direction (total working area) is equal to the sum of the step areas, results in the operation of the diaphragm seal in the sum total known diaphragm seal is the work space assigned to the total work area for the purpose of Pressure setting in the hydraulic system by a hydraulic line connected to a pressure relief valve. This is a major disadvantage to see, because the well-known diaphragm seal only acts indirectly and therefore a special pressure relief valve is to be provided.

The invention is based on the object of designing a diaphragm seal of the type specified at the outset in such a way that that there is no additional pressure relief valve for its function within a hydraulic Plant needed.

The object is achieved according to the invention by the pressure transmitter characterized in spoke 1.

The advantage achieved by the invention is in comparison mi! to see the state of the art in that a hydraulic connection, throttled in the diaphragm seal, between the working circuits of the pumps and the the line containing the mean pressure exists. As a result, there is no need for an additional pressure relief valve, but the line containing the medium pressure can directly connect to the hydraulic Be connected to the system.

According to the developments according to claims 2 and 3, the prevention of power losses is at different operating pressures prevents the pressure medium from overflowing from one circuit into the other, whereby a safe and loss-free function of the diaphragm seal is ensured. So the Operating pressures of several pressure medium sources are averaged in the most precise and safest way. So can for example, the operating pressure of several hydraulic Pumps, already averaged, can be fed to another element in just one feed line, which so far received the different pressures over several supply lines and additionally from its structure had to carry out an averaging of the pressures.

According to claim 2, the aforementioned purpose is achieved in that a check valve is arranged in each discharge line. According to claim 3, a check valve is integrated into the throttle. In this solution, the control edge of at least one of the step surfaces is formed on an annular piston which is mounted between the stepped piston and the housing with axial movement play between two stops on the stepped piston. Due to the displaceability of the annular piston and the stepped piston against each other, depending on the pressure generated, an overlap occurs alternately at the control edges that blocks the return flow of the hydraulic fluid from the medium pressure side to the low pressure side.
In the interests of a simple design and to achieve a low surface pressure on the stop surfaces, it is advisable to form the stops by means of ring shoulders.

The diaphragm seal according to the invention has the great advantage that it simplifies complex hydraulic Components contributes. There is also the advantage that a component which is responsible for the function is designed only with one operating pressure, now with the operating pressures of several

Pressure sources can be fed as the working pressure only passes through a supply line through the pressure transmitter is fed. For example, a controller that was previously only used to control a single feed pump could be used by interposing the pressure transmitter according to the invention for regulation can be used by two or more feed pumps at the same time.

The invention makes it possible to use the known diaphragm seal, which has a complex structure and a additional pressure relief valve required for its function, practically structurally to a single-acting one Simplify cylinder.

Two embodiments of the invention are described below with reference to the schematic drawing, s \ explained in more detail. It shows

1 shows a diaphragm seal in section as a first exemplary embodiment ;

Fi g. 2 shows a pressure transmitter in section as a second exemplary embodiment;

Fig. 3 shows the second embodiment in another Functional position.

The diaphragm seal, designated as a whole by 1, has a stepped piston 2, the two step surfaces 3 and 4 of which are in the same direction are of the same size. The working surface 5, which is arranged in opposite directions to the step surfaces 3 and 4, has a surface which is equal to the sum of the two step surfaces 3 and 4. The stepped piston 2 is arranged in a housing, of which only the inner working spaces are shown. The housing has a first working space 6 into which a feed line 7 with a first operating pressure /? Opens. Furthermore, a second working space 8 is provided, to which a feed line 9 with the second operating pressure p _{2 is} connected. An annular groove 12 and 13 is assigned to each of the two working spaces 6 and 8 or the control edges 10 and 11 of the step surfaces 3 and 4. The control edges 10 and 11 each cooperate with an edge of the annular grooves 12 and 13, respectively. A discharge line 14 and 15 lead away from the annular grooves 12 and 13. A check valve 16 or 17 is arranged in each of the discharge lines 14 and 15. Both discharge lines 14 and 15 are combined with a line 18, from which a branch 19 in turn leads to the work surface 5.

The control edges 10, 11 form, in each case with an edge of the associated annular groove 12 or 13, the throttles with 21 and 22 are designated. The housing is denoted by 23.

The diaphragm seal according to the invention works as follows:

If the operating pressures />, and p ₂ z. B. supplied by two feed pumps via the supply lines 7 and 9 to the diaphragm seal 1, these pressures act on the step surfaces 3 and 4 of the stepped piston 2. You will move the stepped piston to the right to the stop, so that the control edges 10 and 11 of the annular grooves 12 and 13 are completely released. The pressure medium can thus penetrate into the discharge lines 14 or 15 and reach the line 18 via the check valves 16 and 17.

If the two operating pressures of the same size, that is Pi ⁼ Pit ^{so w 'r} d' 18 ⁿ the direction of the pressure /?] = P build ₂ via the branch 19 to the work surface. 5 As a result, the same forces are applied to the piston from both sides. The right stop position of the piston is consequently the floating weight position when the operating pressures are identical, since the mean pressure is identical to the respective operating pressures at the same time.

However, if the case occurs that one of the two operating pressures is higher, the equilibrium position of the stepped piston 2 will change. If, for example, the pressure p _{2 is} greater than the pressure p _f , then after the stepped piston 2 has been pushed into its right stop position, the pressure medium with the higher pressure p ₂ , after it flows through the discharge line 15, is both in the line 18 and also flow into the lower-pressure discharge line 14. As a result, the check valve 16 is closed and the pressure P _{2 is applied} to the work surface 5. Since the higher pressure p _{2 is} now present on the total area, the left-hand thrust generated on this side is greater than the right-hand thrust force caused by the pressures p _x and p _{2 on the small step areas.} The stepped piston 2 is consequently shifted to the left until the control edge 11 of the step surface 4 throttles the liquid flow with the pressure p ₂ until the equilibrium of forces is restored. This equilibrium is reached when the operating pressures are averaged, i.e. when

The stepped piston 2 will consequently, depending on the difference between the two operating pressures p _x and p _2, throttle the flow of liquid to a greater or lesser extent or even release it completely. However, it will always be able to assume a position of equilibrium, so that the working pressure obtained in line 18 will always be the pressure p _m averaged exactly from the operating pressures pi and p ₂ .

As already mentioned, the diaphragm seal can be used in the same way as this using the drawing for two Operating pressures has been described, also designed for the operating pressures of more than two pressure medium sources will. Regardless of how many supply lines or discharges and in connection therewith, how many stages the graduated piston has is the arithmetic mean of all the supplied and the operating pressures in the same direction as the step areas, i.e. the working pressure

"_ Pi + Pi + - ■ - + Pn

can be obtained.

The stepped piston 2 is always pushed into its equilibrium position, so that the several operating pressures on the several equally large surfaces and over the control edges and check valves the total or working area are in equilibrium.

In the second embodiment according to FIG. 2, in which the same parts are provided with the same item numbers are, a check valve generally designated 25 is also provided. The check valve 25 is integrated into the stepped piston 2 or into the throttle 21. It consists of a stepped piston 2 coaxial surrounding annular piston 26, the sealing between the stepped piston 2 and the designated here with 27 Housing mounted uni axially between two stops 28, 29 on the stepped piston 2 is displaceable. The attacks 28, 29 are formed by annular shoulders of the stepped piston 2. The still to be explained movement

game is denoted by s. The end face of the annular piston 26 facing the throttle 22 forms the sliding surface 4 and the control edge 11.

The position shown in Fig. 2 of the stepped piston 2 and the annular piston 26 is set in operation of the pressure separator when the operating pressure / », in the supply line 7 is greater than the operating pressure p ₂ in the supply line 9. In this case, the the end face 31 of the annular piston 26 facing the working surface 5 than at the end face of the annular piston 26 facing the throttle 22, namely the step face 4 _{(p 1} ,> p 2). As a result, the annular piston 26 is acted upon in the direction of the throttle 22 (arrow 32) and it makes contact with the left stop 28. In this stop position, the throttle 22 is closed, while the throttle 21 regulates. Therefore, the pressure p ", cannot get into the supply line 9 and it is applied to the working surface 5 of the stepped piston 2.

The position of the stepped piston 2 and of the annular piston 26 shown in FIG. 3 occurs when the pressure p ₂ in the supply line 9 is greater than the pressure /) in the supply line 7. The annular piston 26 is therefore in the direction of the arrow 33 is applied so that it abuts the stop 29 because p _{2 is} greater than p, ". In this functional position, the throttle 22 (control edge 11) regulates while the throttle 21 is closed, because the stepped piston 2 has been moved towards the throttle 21 by the amount of movement s compared to the position in the functional position according to FIG. 2, whereby it closes it, which can be clearly seen in the drawing.

The movement play .ϊ is dimensioned so large that the control edge 11 can be adjusted so far in both axial directions in comparison to the control edge 11 of the first embodiment that it is able to close the throttle 22 in the regulating position of the throttle 21 (FIG. 2 ) and in its own control position (FIG. 3) the stepped piston 2 is able to close the throttle 21. The displaceability of the annular piston 26 and thus the control edge 11 or the displaceability of the annular piston 26 and the stepped piston 2 against each other changes the distance α or e _{2 of} the two control edges 10, 11 depending on the respective pressure ratio pjp \ or pjpi in the functional position according to FIG. 3 adjusting distance a _; is greater by the amount of play s than the distance β which is established in the functional position according to FIG. The resulting overlap alternately on the control edges 10, 11 blocks the return flow of the hydraulic fluid from the medium pressure side (line 18) to the low pressure side (supply line 7 or 9).

If the pressure /, and the pressure p _{2 are the} same, the annular piston 26 operates as a pressure compensator, whereby it is subjected to the same pressures on both sides (step surface 4, end surface 31) (/ j, = p ₂ = p _m ) . The annular piston 26 assumes a position between the stops 28, 29, which is automatically regulated, the throttle cross-sections of the throttles 21, 22 adapting to one another.

If several annular pistons 26 are present in a stepped piston 2 having more than two stages, each requires a connecting line (not shown) between the line 18 and the housing 27, around the end face 31 of the annular piston 26 facing away from the associated throttle with the averaged pressure to apply. In the embodiment according to FIG. 2 and 3 there is no need for such a line, because the end face 31 is at the end of the stepped piston 2 and thus automatically with the averaged Pressure is applied.

For this purpose 2 sheets of drawings

Claims (4)

Patent claims: 1. Diaphragm seal for providing an averaged working pressure from the operating pressures of at least two pressure medium sources, in particular hydraulic pumps, for averaging the operating pressures a stepped piston is provided, the number of which is of the same size and of the same size Stepped areas corresponds to the number of operating pressures to be averaged, the opposite working area of which is equal to the sum of the step areas and that in a correspondingly graduated and with Supply lines for the housing provided with operating pressures is slidably guided, characterized in that that in the housing (23, 27) each have a control edge (10, 11) of the respective step surfaces (3, 4) associated annular grooves (12, 13) are provided and that away from the annular grooves (12, 13) Derivatives' J4,15) are provided, which start with a common line (18) for the averaged pressure are connected, which in turn is connected to the work surface (S) is in communication. 2. Diaphragm seal according to claim 1, characterized in that that to prevent power losses at different operating pressures in a check valve (16, 17) is arranged on each discharge line (14, 15). 3. Diaphragm seal according to claim 1, characterized in that at least one of the step surfaces (4) and the associated control edge (11) is formed on an annular piston (26) which is between the stepped piston (2) and your housing (27) with axial play (y) two stops (27, 28) are displaceably mounted on the stepped piston (2), the movement play (s) being a displacement of the annular piston (26) from a throttle (22) formed by the associated annular groove (13). predetermined normal position in both axial directions (arrow 32,33) and the averaged pressure can be applied to the end face (31) of the annular piston (26) facing away from the throttle (22). 4. Diaphragm seal according to claim 3, characterized in that the stops (28, 29) through Ring shoulders of the stepped piston (2) are formed. A mean pressure Pn, for which the following dependency exists: