DE1936506A1 - Control valve unit - Google Patents

Description

Control valve unit The invention relates to a control valve unit, which is interposed between a pressure source and a low-pressure space, to control a pressure difference with which the actuation of a pressure medium-actuated Device is controlled as a function of a predetermined input signal.

The invention is based on a control valve unit a valve device arranged in a housing, which is connected between a Pressure source connectable supply inlet and one to a low pressure chamber connectable return outlet is interposed and depending on a predetermined input signal two separate outlet openings, which are connected to a pressure medium-actuated Device can be connected, optionally with the supply inlet or the RtekfUhrungsauslaß connects.

According to the invention, the control valve unit is characterized in that that the valve device can be moved by a valve which is responsive to a pressure difference Adjusting device can be actuated, with an effective surface of the adjusting device the pressure difference between the two outlet openings is exposed, so that the Adjusting device through this pressure difference in one of two opposite opening positions is moved, depending on the direction of the input signal that the actuation initiates the valve device and the actuating device.

Here, the valve device can be used as a two-position control valve be understood that in the open position in which it depends on the sense of direction of the input signal is initially moved, remains until the input signal has a assumes the opposite predetermined value which is large enough to operate the two-position control valve against the compressive force created by the pressure difference between the outlet openings is exerted on the effective area of the actuating device to switch. Significant is in particular that the two-position control valve in one of its remains in both opening positions, although the input signal is the two-position -The control valve has forcibly switched to the relevant open position decreases a value that is smaller than the original value, and even becomes zero.

In a further embodiment of the invention, a pressure medium actuated double-acting servomotor, characterized in that a control valve unit according to the invention to control the Actuation of the servomotor actuator provided is that on the pressure difference between the opposite to the outlet openings the control valve unit connected pressure chambers responds, and that a with the actuator operatively connected input signal control valve is provided is that the actuation of the valve device as a function of the displacement of the actuator controls.

With normal pressure medium supply, the servomotor works automatically and continuously until an output force - the pressure differential force acting on the actuator compensates and thus counteracts any further displacement of the actuator.

Exemplary embodiments of the invention are explained in more detail with the aid of the drawings explained. 1 shows a cross section through a control valve unit according to the invention, FIG. 2 shows a servomotor according to the invention with a control valve unit according to FIG. 1.

In Fig. 1, a control valve unit 10 is shown, the actuation a double-acting pressure medium actuated servo motor 12 controls. The piston 14 of the servomotor is the pressure difference between the two pressure chambers 16, 18 of the servomotor exposed to actuate an actuator 20.

The housing of the control valve unit 10 has a partition body 22, on each of its two end faces an annular body 24 and an end wall body 26 are tightly attached. The partition body 22 has a pressure source (not shown) connected supply inlet 28, one to a low pressure space (for example the atmosphere) connectable return outlet 30 and two outlet openings 32, 34, which are connected to the pressure chambers 16, 18 of the servomotor via lines 36, 38 are. The inner portion 40 of the bulkhead body 22 is essentially two in number understand parallel bores 42, 44, of which the bore 42 with the Supply inlet 28 and bore 44 connected to return outlet 30 is. Each of the bores 42, 44 opens into two separate outlet chambers 46, 48, of one connected to the outlet 32 and the other to the outlet opening 34 In the bore 42 a rod 50 is slidably arranged, the length of which is greater than the axial length of the bore 42. At the opposite ends of the pole 50 two valve bodies 52, 54 are attached, which with the opposite, edges 46, 48 of the bore 42 serving as valve seats cooperate to form the supply inlet 28 with the outlet chamber 46 or the outlet chamber 48, through the between the rod 50 and the bore 42 formed channels to connect. In the same Way, a rod 60 is slidably mounted in the bore 44, whereby the outlet chambers 46, 48 can each be connected to the return outlet 30. The rod 60, whose Length greater than that axial length of the bore 44 is at their opposite ends provided with two valve bodies 62, 64, which with the opposite edges 66 or

68 of the bore 44 cooperate.

The outlet chamber 46, 48 are formed by two elastic membranes 70, 72 closed at their outer ring sections between the partition body 22 and the annular bodies 24 are clamped so that they have two control chambers in the housing 74, 76 form.

Each of the diaphragms 70, 72 is also attached to a valve body 50 or 54 attached, whereby a movable adjusting device is formed, on the one hand on the pressure difference between the outlet chambers 46, 48 and on the other hand on the Pressure difference between the control chambers 74, 76 responds.

The control chambers 74, 76 are, on the one hand, transmitters with throttling points 79, 81 provided channels 78, 80 with the supply inlet 28 and on the other hand over Throttle points 86, 88 with vent openings 82, 84, which are connected to a low-pressure chamber (e.g. the atmosphere) are connected. With the as a valve seat the-1 nenden edges of the throttle openings 86, 88 act two diaphragms 90, 92, the at their clean ring sections between the ring bodies 24 and the end wall bodies 26 are clamped together to control the pressure in the control chambers 74,76. Each membrane 90, 92 divides the space between the annular bodies 24 and the end wall bodies 26 into a ventilation chamber 94 or 96, which is connected to the ventilation opening 82 or 84 connected, and one Input signal control chamber 98 or 100, which is connected to an input signal control inlet 102 and 104, respectively.

In the inner section 40 of the partition body 22 there are throttle channels 106, 108 are provided which connect the outlet chambers 46, 48 to the return outlet 30 associate. The effective flow cross-section of the supply channel, which is through the Bore 42, rod 50 and valve body 52 or 54 defined becomes essential selected to be larger than the effective flow cross-section of the ventilation duct, the is defined by the bore 44, the rod 60 and the valve body 62 or 64.

The control valve unit described works as follows: Let it be for example assume that the two input signal control inlets 102, 104 are connected to a pressure control device (not shown> are connected, which have a relatively small pressure difference input signal to the two input signal control inlets 102, 104. The pressure differential input signal can, for example, consist of two complementary digital signals, i.e. two separate ones Pressure signals exist, one of which (input signal 1) is a given Pressure value corresponds to that which is greater than the pressure value of the other pressure signal (input signal 0) is. It is also assumed that the various valve parts are initially are in the position shown in Fig. 1, in which the pressure chamber 18 of the servomotor via the bore 42, the outlet chamber 48, the outlet opening 34 and the line 38 with the supply inlet 28 and the pressure chamber 16 via the bore 44, the outlet chamber 46, the outlet port 32 and the line 36 with the return outlet 30 is connected. The movable supply valve 50, 70, 72 is through the-between the pressure difference prevailing in the control chambers 74, 76) affects the effective area of the membranes 70, 72 acts, as well as by acting between the outlet chambers 46, 48 Pressure difference that is applied to the effective area of the membrane minus the effective cross-section of the valve seat 56 or 58 acts, held in the position shown.

The movable vent valve 60, 62, 64 is through the between the outlet chambers 48 and 46 prevailing pressure difference, which on the effective area of the valve body 62 acts, held in its position shown.

When the input signal control port 104 is supplied with a pressure signal that is greater than the pressure in the venting chamber 94, is acted upon, and at the same time the input signal control inlet 102 to a low pressure space (e.g., the Atmosphere), the membranes 90, 92 move to the right (in Fig. 1), releasing the throttle opening 86 and moving the throttle opening 88. The pressure in the control chamber 74 decreases until it is due to the throttle opening 79 is substantially equal to the pressure in the vent chamber 94, while the pressure in the control chamber 76 increases until it is substantially equal to the pressure in the supply inlet 28 is. The resulting pressure difference between the control chambers 76, 74 is overcome the pressure difference acting on the diaphragms 72, 70 and moves the supply valve 50, 70, 72 to the right (in Fig. 1), whereby the connection between the outlet chamber 118 and the supply inlet 28 interrupted and the supply inlet 28 is connected to the outlet chamber 46. Due to the different flow cross-sections of channels 42 and 44 and channel 108 is moved by the compressive force created by the pressure difference between the two outlet chambers and the dynamic pressure force (Berno'ulli pressure force due to the flow between the bore 42 and the return outlet 30) arises, the vent valve 60, 62, 64 to the left (in Fig. 1), whereby the connection interrupted between the outlet chamber 46 and the return outlet 30 and the return outlet 30 is connected to the outlet chamber 48 and the pressure chamber 18. After the through the input signal controlled displacement of the supply valve 50 takes place Movement of the vent valve 60 abruptly as the vent valve closes at this point in time is in an unstable, pressure-releasable state. if the supply valve 50, 70, 72, as described above, has been switched over, the supply valve remains in its right open position, independently of how the input signal is in the input signal control port 104 in the following changes. To switch the control valve unit to its opposite open position and thus to reverse the displacement of the actuator 20, all that needs to be done is the throttle opening 88 opened and the throttle opening 86 closed, which happens as a result that a pressure signal is delivered to the input signal control inlet 102 and the input signal control inlet 104 is connected with the atmosphere.

By changing the effective flow cross-section of the throttle openings 79 and 81 can set the delay in the response of the control valve unit 10 will. Due to the large difference between the effective area of the membranes 90 and 92 and the relatively small cross-section of the channels 86 and 88 can the input signal to be entered at 102 or 104 is generated by a pressure, which is very small with respect to the pressure in the venting chambers 94, 96.

In the embodiment shown in Fig. 1, the two-position valve device controlled by a pressure difference, which is controlled by two complementary acting input signal control valves 86, 90 or 88, 92 is produced in separate control chambers 74, 76. The throttle openings 86, 88 can, however, also be arranged in such a way that they are controlled by a single valve body controlled responsive to an input signal; the supply valve 50, 70, 72 could be derived directly from a pressure differential input signal sent to the control chamber 74, 76 or even by a mechanical acting on the rod 50 Input force can be controlled.

In particular, the throttle openings 86, 88 of two valve elements 90 'and 92' are controlled on the movable actuator 20 of the servomotor 12 are attached (Fig. 2). In this embodiment, the atmosphere is used as a pressure source, which the supply opening 28 and the throttle openings 86, 88 with Pressure supplied, while the return outlet 30 to a negative pressure space (not shown) is connected. With such an arrangement, the control valve unit controls 10 continuously and automatically those in opposite directions movement of the piston 14 until an output force acts on the piston 14 acting compressive force compensates.

Claims (10)

Claims n 1st control valve unit with a valve device arranged in a housing, between a supply inlet that can be connected to a pressure source and a is connected to a low-pressure chamber connectable return outlet and depending on a given input signal, two separate outlet openings> which can be connected to a device that can be operated by means of a pressure medium, optionally with connects the supply inlet or the return outlet, characterized in that that the valve device (50, 60) by a responsive to a pressure difference movable adjusting device (70, 72) can be actuated, an effective area of the Adjustment device for the pressure difference between the two outlet openings (34, 36) is exposed, so that the adjusting device by this pressure difference in one of two opposite opening positions is moved, namely each after the sense of direction of the input signal indicating the actuation of the valve device and the actuating device initiates. 2. Control valve unit according to claim 1, characterized in that a second effective area of the actuating device (70, 72) one of the input signals is exposed to the entered pressure difference. 3. Control valve unit according to claim 2, characterized in that the pressure difference input signal by the pressure difference between two in the housing (22, 24, 26) provided separate control chambers (74, 76) is defined, of which Each connected to the supply inlet (28) and the return outlet (30, 82, 84) is, in each case via a throttle opening (79, 86; 81, 88), one of which (86, 88) can be controlled by a control valve (90, 92), and that the second effective Actuator area closely exposed to the input signal pressure differential is significantly larger than the first effective actuator area, which is the pressure difference is exposed between the outlet openings. 4. Control valve unit according to claim 3, characterized in that Each of the control valves (90, 92) that control the pressure in the separate control chambers (74, 76) can be actuated by a piston or a membrane (90, 92), the or those on the pressure difference between one to an input signal control inlet (102, 104) connected input signal Control chamber (98, 100) and a vent chamber connected to the return outlet (82, 84, 30) (94, 96) responds. 5. Control valve unit according to one of the preceding claims, characterized characterized in that the valve device (50, 60) is connected to the adjusting device (70, 72) effectively connected two-position supply valve (50, 52, 54, 56, 58) and a pressure actuated vent valve (60, 62, 64, 66, 68) of which the supply valve depending on the input signal the connection of the Supply inlet (28) with one or the other of two separate ones to the outlet openings (32, 34) connected outlet chambers (46, 48) controls and the vent valve depending on the pressure difference between the outlet openings, the low-pressure outlet chamber connects to the return outlet (30), the effective flow area of the vent valve (60) is much smaller than the effective flow cross-section of the supply valve (50). 6. Control valve unit according to claim 5, characterized in that Each of the outlet chambers (46, 48) directly with it via a throttle channel (106, 108) the return outlet (30) to prevent the fluid pressure in which one of the two outlet chambers is enclosed when the vent valve (50) moved into the position in which the supply inlet (28) with the other outlet chamber connected is. 7. Control valve unit according to one of the preceding claims, characterized characterized in that the valve device (50, 60) is provided in one in the housing rigid partition body (22) slidably arranged and on their opposite Ends with two oppositely acting movable membranes (70, 72) of substantially the same effective area is provided in connection with the housing and the Partition body form two separate outlet chambers, which are connected to the outlet openings (32, 34) are connected. 8. Control valve unit according to one of claims 2 to 6 in connection with claim 7, characterized in that the second effective surface of the adjusting device (70, 72) responsive to the pressure differential input signal are opposite of the directed surfaces of the membranes (70, 72), which the the pressure of the outlet chambers (46, 48) facing exposed surfaces of the membranes is formed. 9. Control valve unit according to claim 5 or 6 in conjunction with claim 7, characterized in that the supply valve (50, 52, 54, 56, 58) is two opposite, interconnected valve body (52, 54), which with the membranes (70, 72) are operatively connected and one or the other two opposing openings (56,58) of a supply channel (42) which in the partition body (22) is provided to the supply inlet (28) with the to connect both outlet chambers (46, 48). 10. Druckmittelbetätigbaren5 double-acting servomotor, thereby characterized in that a control valve unit (10) according to one of the preceding Claims for controlling the actuation of the servomotor actuator (12, 14) are provided is that on the pressure difference between the opposite, to the outlet openings (32, 34) 'responds to the pressure chambers connected to the control valve unit, and that an input signal control valve (90 ', 92 ') is provided that the actuation of the valve device in accordance controls with the displacement of the actuator.