DE2513548B2 - Device for controlling the delivery rate of adjustable axial piston pumps - Google Patents

Description

is tense, is the starting position of the control device precisely fixed in the unpressurized state. It is controlled by applying a force via the Gebeiglied, whereby the force equilibrium of the Stabilizing springs on the control spool are disturbed and an adjustment process is initiated. Still is between The stabilization springs ensured the stability of the control device in every setting state. Opposite to the main patent has the additional advantage that in the event of an override by Pressurization of the control chamber no additional stops are provided for the transmitter member to enable the override that does not affect the control setting.

Appropriate structural designs are identified in the unclaims. For example embodiments the invention are described in more detail below with reference to the drawings. It shows

F i g. 1 schematically in section an embodiment of the invention for a two-sided, d. H. adjustable pump for conveying directions;

2 in a sectional view in a detail further embodiment of the control slide with transmitter device;

F i g. 3 schematically in section an embodiment of the invention for a one-sided, d. H. in a Flow direction adjustable pump and

F i g. 4 is a performance diagram.

The in F i g. 1 schematically shown pump 1 is with the help of a double-acting adjusting piston 2 within a servomotor adjustable, the starting position of which, for example, the illustrated zero position of Centering springs 3 and 4 is set. The end faces 5 and 6 of the actuating piston 2 close the actuating cylinder spaces 7 and il, which are connected via lines 9, 10 within the Housing of the actuating device with the control and regulating device according to the invention described in more detail below stay in contact.

The actuating piston 2 stands via a double lever 11 engaging it in the middle, on the one hand with a symmetrically designed control slide 13 arranged in the housing 12 of the actuating device and, on the other hand, with a member 13 'that is slidably mounted in the housing 12 and is acted upon on both sides by sets of springs 14 and 15 , in an articulated non-positive connection. The spring sets 14 and 15 consist of one behind the other, supporting springs 14a and 146bzw. 15a and 156, which have different spring characteristics, so that each spring set 14 and 15 has a degressive characteristic, for reasons which will be discussed below in connection with FIG. 4 will be explained. The control slide 13 arranged in the housing 12 has control edges 16, 17 and 18, 19 Ie after the position of the control slide, the control edge 16 opens the connection between the line 10 and a line 20 and at the same time the control edge 19 opens the connection between the line 9 and the Housing interior 27, which is connected to the drain, not shown. Or the control edge 17 establishes the connection between the line 9 and a line 21, while at the same time the control edge 18 establishes the connection between the line 10 and the interior space 27 and thus the waste. The lines 20 and 21 are connected to the working pressure lines 25 and 26 of the pump 1 by a connecting line 22 via check valves 23 and 24, respectively. The required hydraulic oil is fed to the working pressure lines 25 or 26 of the working circuit of the pump by an auxiliary pump 60 via a line 61 and check valves 62, 63, the check valves 62, 63 ensuring that the hydraulic oil is always fed into the low-pressure working pressure line 25 or 26 takes place
At each end of the control slide 13 there is arranged a control piston 28 or 29 that is movably guided coaxially to the control slide, each control piston 28 or 29 delimits a control chamber 30 or 31 located between it and the control slide end, which constantly

ίο via lines 64 or 65 with the connecting line 22 and is thus connected to the respective working pressure line 25 or 26 carrying the working pressure The travel of the control piston 28 or 29 is set by a stop 32 with respect to the respective end of the control slide or 33 limited. On the side facing away from the slide end, each control piston 28 or 29 is connected to the movable core 34 and 35 of electromagnets 36 and 37 fixedly connected or in contact. The cores 34 or 35 lie on the respective control piston 28 or

29 sides facing away from abutments 66 and 67, respectively. Stabilizing springs 38 and 39 are prestressed between these abutments 66 and 67, respectively, and abutments 70, 71, which can be adjusted by means of screws 68, 69 with respect to the housing. The control slide 13 is force-locked between the stabilizing springs 38 and 39, since the cores 34 and 35 are in contact with the control pistons 28 and 29 and these are in contact with the control piston 13 via the stops 32 and 33, respectively.
The setup works as follows:

If, for example, the electromagnet 36 is activated by the supply of electric current, it is moved its core 34 in Fig. 1 to the left and it follows by increasing relaxation of the pretensioned Stabilizing spring 39 of the control slide 13 and also the control piston 28, 29 to the left. At the same time, the Stabilizing spring 38 is more strongly biased. In other words, activating one of the Magnets 36 or 37 disturbed the balance of forces of the prestressed stabilizing springs and after moved to one side. By moving the control slide 13 to the left, the control edge 17 opens the connection between the line 9 and 21 and the control edge 18 opens the connection between the Line 10 and the interior space 27, d. H. the drain.

From the connecting line 22 via the lines 21 and 9, the actuating cylinder space 7 is supplied with pressurized oil provided. Since the actuating cylinder space 8 is connected to the drain via the lines 8 and the space 27, the actuating piston 2 moves in FIG. 1 to the right and adjusts pump 1 in the direction of a larger flow rate, for example in the working pressure line 25, so that the line 25 is the pressure-feeding working pressure line and the line 26 becomes the low pressure line. By moving the setting piston 2 to the right the spring set 14 is increasingly biased via the double lever 11, until its increasing force moves the control slide 13 back to its starting position, in which the control edge 17 and 18 close the lines 9 and 10 again.

ω This is the usual mode of action of a path-dependent Follower piston control.

After completion of this adjusting process described for example, the control piston 28 is supported the stop 32 of the control slide 13 with a force

<> ">, which results from the difference between the magnet 36 exerted force and the tension force of the spring set pretensioned by the adjusting process Differential force is a measure of the performance of pump 1.

If the working pressure in the working pressure line 25 as a result of too high performance demands on the Working pressure line 25 connected, not shown consumer that by the said differential force exceed a certain amount, an override occurs by the control piston 28 and thus Swing back pump 1 as follows:

The control chamber 30 is connected to the connection line 22 via the line 64 and this to the working pressure line 25 in connection. If the working pressure in line 25 increases to an undesirable extent, it lifts in the control chamber 30 also acting pressure against the said differential force the control piston 28 from Stop 32 of the control slide 13. The control slide 13 moves according to FIG. 1 to the right and the control edges 16 and 19 open. As a result, the line 9 is connected to the drain, the line 10 is connected to Working pressure is applied so that, conversely to the process described above, the actuating piston 2 of the Servomotor for adjusting the pump 1 is moved to the left and the pump 1 to a smaller delivery rate is pivoted back. This pivoting back takes place until there is no further increase in the Working pressure in the line 25 takes place more and the control slide 13 returns to its starting position. In other words, there is then the force, the force exerted by the pressure in the control chamber 30 the stabilizing spring 39 and the force of the spring set 14 back in equilibrium.

The from Fig. 2 visible modification of the device represents a particularly simple structural design with the training according to FIG. 1 matching parts are given away with the same reference numerals. Of the Control slide 13 has on its two end faces 40, 41 bores 42, 43 in which as a control piston acting and trained plungers on the movable cores 34, 35 are movably sealingly guided and Define control rooms 46, 47. These are via bores 48, 49, the annular spaces 50, 51 and the line 52, 53 are constantly connected to the connecting line 22 carrying the respective working pressure. the The function of the control rooms 46, 47 corresponds to that of the control rooms 30, 31 described above Lines 52, 53 correspond to lines 20, 21, 64, 65 of FIG. 1. The function of stops 32, 33 according to F i g. 1 are taken over by the end faces 40, 41, to which the step at the transition of the magnetic core 34 or 35 in the plunger 44 and 45 respectively.

In Fig. 3 shows an embodiment of the control device according to the invention for a pump 80 which can only be pivoted to one side. The pump 80 is adjusted by a servomotor 81, the actuating piston 82 of which is in engagement with the adjusting lever 83 of the pump 80. The adjusting piston 82 is adjacent cylinder chambers 84 and 85 from each other and ^r is r, biased by a spring 86 into its initial position. A line 87 opens into the cylinder space 84 and a line 88 opens into the cylinder space 85 within the housing 89 of the actuating device. In a longitudinal bore of the housing 89 there is arranged a control slide 90 which has control edges 91, 92, 93 and 93 '. The control slide 90 is acted upon by a spring 94 at its one end, the left end in FIG. At the other end, the control slide 90 rests on the core 96 of an electromagnet 97, which in turn is supported by a stabilizing spring 100 pretensioned between abutments 98 and 99. The control slide 90 has at its in FIG. 3 right end face 101, which faces the core 96 of the magnet 97, has a bore 102, into which a plunger 103 of the core 96 protrudes as a control piston and is guided in the bore 102 in a movably sealing manner. The bore 102 forms, delimited by the plunger 103, a control chamber 104 which is continuously connected to the annular chamber 106 via a bore 105. The annular space 106 and the annular space 108 connected to it by a line 107 are connected to the working pressure line 112 of the pump 80 or a control pressure line 113 via a line 109 and check valves 110, U1. The annular space 114 is connected to the drain 115.

The setup works as follows:

The device works in principle in the same way as with the one based on FIG. 1 described control and override process. The only essential modification is that the spring 94 simultaneously performs the function of the Control slide 90 frictionally clamping and stabilizing spring 100 counteracting stabilizing spring takes over If the electromagnet 97 is activated, its core 96 moves in the direction of the indicated arrow to the right in Fig.3. The bias of the stabilizing spring 100 is thus partially taken from the control slide 90 and this moves under the bias of the spring 94 To the right. The control edges 91 and 93 open so that the cylinder chamber 84 via the line 107 and the Annular space 106 is connected to line 109 and pressurized oil is applied (either from the Working pressure line 112 or from the auxiliary pressure line 113). The cylinder space 85 is via the line 88 and the control edge 93 is connected to the drain 115. Of the Actuating piston 82 moves in FIG. 3 to the left, the pump swivels to larger flow rates, as follows long until the spring 94, which is more and more relaxed by the movement of the actuating piston 82 to the left Control slide 90 can also be moved to the left until it reaches its starting position again and close the control edges.

The override process for power control takes place in that increasing working pressure in the Line 112 via line 109 and bore 105 in the control chamber 104 comes into effect and from a pressure value predetermined by the spring 94 the Control slide 90 moved to the left in FIG. The cylinder space 84 is created by the opening control edge 92 is connected to the drain and the cylinder space 85 is connected to the annular space 106 via the control edge 93 ', so that the actuating piston 82 is moved to the right, namely long until the increased bias dei Spring 94 is moved back to the right into its starting position via the rod 95 of the control slide 9.

The line 113 connected to the line 109 is an example of the fact that the supply of the pump supply position and / or the application or influencing of the control room 104 also with the help of separate Pressure medium sources, not shown, can take place instead of the working pressure line. As a result, sin < further control and regulation options opened up, wi (e.g. pressure control, stepless change de Basic service and the like. This also applies to the embodiments according to FIG. 1 and 2 if dii Connecting line 22 not with the Arbeitsdrucklei lines 25 or 26 but with a separate nich Rcgcldruckleitung shown is connected. The control rooms 30,31 according to Fi g. 1.46.47 nacl

15th

Fig. 2 are influenced in different ways, so with different not shown Control pressure lines are connected and the spring sets 14, 15 can be different from one another Have characteristics in order to realize asymmetrical control characteristics.

The influence of the design of the spring sets 14 and 15 in FIG. 1 is illustrated below with reference to the performance diagram according to FIG. 4 explained.

In Fig. 4 mean: to

P = power,

Q = delivery flow,

Pb = operating pressure (working pressure),

Fm = differential force between that on the control spool acting force of the magnet and force of the spring set,

S = travel (swivel travel) of the pump.

Since the actuating force of the electromagnet can be viewed as constant , the line labeled Fm in the diagram of FIG. 4 essentially the course of the spring characteristics of the spring set (14 or 15 in Fig. 1). For regulation to constant power, there is an effort to match the regulation as precisely as possible to the theoretical, dot-dash hyperbola of constant power P. This theoretical performance curve can only be achieved with a set of springs in the device according to the invention which has a characteristic which corresponds to the dash-dotted line A in FIG. This theoretical characteristic cannot be achieved in practice with a set of springs. A relatively good approximation is achieved by the inventive design of the spring sets 14, 15 as each degressively acting spring salt. The "false" spring characteristic is ensured by the fact that the spring 146 responds first (or in the opposite direction when it is swung out) and, once this spring has reached a certain pre-tension, the second spring 4.Ί (or 15a) becomes active comes, whereby the springs 14.i and Ι4ύ or 15a and 156 act one behind the other. Branch B of curve L · Fm corresponds to the effect of one spring 146 or 156. Branch C corresponds to the effect of two springs 14a and 146 or 15.7 and 156 connected in series. The output curve is then obtained for power control with the device according to the invention D, which can be seen to approximate the theoretical curve for constant power P. Line further approximation could be achieved, for example, by means of three-part spring sets.

Are simple compression springs with linear characteristics used as springs, such as the The embodiment according to FIG. 3, the spring 94, is a simple one with the control device according to the invention Realized zero stroke control, in the case of a predetermined working pressure in line 109 acts, the pump 90 is pivoted back practically linearly into the zero position. In the embodiment according to F i g. 3, a progressive set of springs (not shown) is required to implement a power control.

For this purpose 3 sheets of drawings

Claims (4)

Patent claims: 1. Device for controlling the delivery rate of adjustable axial piston pumps, their adjustment is effected by a transmitter device, which is fed via a control slide with non-positive feedback controls a servomotor operated by an auxiliary oil circuit via a spring, the transmitter device one which is arranged in a cylinder space and can be acted upon by a predetermined transducer force Includes control piston, the movement of which is limited by a stop on the control slide and which delimits a control space which is connected to a control valve which determines a control pressure is, and in which the sensor element acting on the control piston with the transducer force is the movable one The core of a proportional solenoid is connected to the control piston, according to Main application 2456381, characterized in that that the control slide (13, 90) between two prestressed stabilizing springs (38, 39; 94, 100) is clamped and the control piston (28, 29; 44, 45; 103) by the force of one of the Stabilizing springs are biased against the stop (32, 33; 40, 41; 101) on the control slide (13; 90) and the core (34,35; 96) of the proportional magnet (36, 37; 97) with its in the case of a control set sensor force against the force of the stabilizing spring preloading the control piston acts on the control piston. 2. Device according to claim 1, characterized in that the core (34, 35; 96) on one Abutment (66, 67; 98) of the stabilizing spring (38, 39; 100) rests and in the case of a regulation the Effect of the pretensioning force of the stabilizing spring on the setting piston (28, 29; 103; 44, 45) degrades. 3. Device according to claim 1 or 2, characterized in that the control piston (44, 45; 103) and the core (34, 35; 96) are formed in one piece and the control piston is formed from one formed on the core The plunger (44, 45; 103) is inserted into a bore (42, 43; 102) protrudes within the control slide (13; 90). 4. Device according to one of the preceding claims, characterized in that one of the Stabilizing springs formed by the spring (94) for returning the control slide (13, 90) is. The invention relates to a device of the type specified in the preamble of claim 1 according to main registration 24 56 381. Such devices are intended to adjust the flow rate of a pump by a force or a Pressure can be controlled and when a predetermined pump pressure or predetermined pump pressure is reached Pump output should be a hydraulic override of the delivery rate value specified by the encoder can be made possible without influencing the value set on the encoder, so that after omission the override, the value set on the encoder takes effect again immediately. The one corresponding to the genre of the main application Device has become known, for example, from DT-PS 19 21 298. In this case, a a master oil pressure adjusting servo valve is provided and the control slide points for each setting direction a control room which is connected to the amplifier stage of the servo valve. This helmsman of the The control slide is designed as an annular piston, which is displaceable with respect to the control slide Control piston divided into two separate annular spaces, the movement of the annular piston on the one hand by a stop on the control valve and on the other hand by a collar on the valve body is limited. One of the annular spaces thus formed is connected to the amplifier stage of the servo valve and the other annulus communicates with the control valve. The arrangement of annular spaces separated by annular pistons in the control space of the Control slide is achieved that the effect of the setting specified by the servo valve (transmitter device) of the master oil circuit is overridden by the control circuit containing the control valve without the both circles directly influence each other. The disadvantage of the described known arrangement, that high demands on the manufacturing accuracy of the control rooms of the control slide and in particular, the annular piston are also provided, since the annular piston takes the master oil circuit from the control oil circuit need to separate. In practice, the passage of a certain amount of leakage oil to the guide and Do not avoid the sealing surfaces of the annular pistons, which would result in a falsification of the control system. The subject matter of the main application is a structurally particularly simple design of the Control slide proposed through which even with direct mechanical action of a transmitter force Direct hydraulic override of the master force on the control spool without any change the specified encoder force is possible and a falsification of the control by leakage oil is avoided. In this case, in an appropriate embodiment of the subject matter of the main application, the control piston can also be used the encoder member acting on the encoder force can also be the movable core of a proportional magnet. Force-controlled control valves with proportional solenoids tend to be unstable. LJm this too prevent, it is from the Krausskopf pocket book "oil hydraulics and pneumatics", components II, p. 71, known to arrange a spring between the valve and magnet, as this makes this spring an energy store acts and the system is stabilized. The present additional patent is based on the task that corresponds to the main patent, with the additional requirement that a stabilization of the device is to be achieved. Appropriate training of the subject matter of the main patent is used to solve this problem proposed that the control slide is clamped between two prestressed stabilizing springs and the control piston by the force of one of the stabilizing springs against the stop on the control slide is biased and the core of the proportional magnet with its in the case of a controller set transducer force against the force of the stabilizing spring preloading the control piston acts on the control piston. Due to the fact that the control spool is frictionally engaged between the pre-tensioned stabilizing springs