SE466321B - SELF-CONTROL PRESSURE CONTROL VALVE - Google Patents

Description

466 321 ' 10 15 20 25 30 35 In order to achieve the object of the invention it is achieved in one A self-regulating pressure control valve comprising de: a pressure control valve unit, a detection unit for detecting secondary pressure, a pressure control unit for regulating the customer pressure in the pressure control valve unit, a drive unit for operate the pressure control unit, a control unit for controlling the drive and a pressure setting unit to set a set print.

The control unit controls the drive unit on the basis of the functional the relationship between the position of the pressure control unit and the pressure corresponding to the controlled pressure to adjust the secondary pressure to a desired value, namely the set pressure value the.

In one embodiment of the present invention comprises the control unit a computer or calculation unit including the arithmetic ethical bodies, correction bodies and memory bodies.

In accordance with the present invention, when one randomly selected pressure is set using the pressure setting the unit working body in the control unit calculates a suitable position for the pressure regulating element in the pressure regulating unit on of the functional relationship between the secondary pressure and the the position of the pressure regulating element, after which the control unit sends a control signal to the drive to adjust the position for the pressure regulating element to a calculated, suitable position tion, so that the secondary pressure is adjusted to the set the pressure.

When the secondary pressure has thus been adjusted to the setting da pressure, the self-regulating valve unit starts mechanically pressure control operation in a conventional manner. Then further fine steering of the secondary pressure is necessary, it is desirable to provide one secondary pressure detecting means for detecting the secondary pressure continuously or periodically and control the drive by means of a correction signal calculated by means of said working means in the control the unit based on the difference between the set pressure and the detected secondary pressure for controlling the secondary pressure continuously or periodically. _ __ g In this way, the self-regulating pressure control valve has ability to respond quickly to variations in secondary pressure and immediate a) p 10 15 20 25 30 35 466 321, regulate the secondary pressure, ie the controlled pressure, to one set pressure, ie a desired pressure or malt pressure.

The above and other objects, features and advantages with the present invention will become more apparent from the following the description of some preferred embodiments of the invention in connection with the accompanying drawing, in which: Figure 1 is a fragmentary sectional view of a self-regulator pressure control valve, in particular showing its pressure control unit; Figure 2 is a graph showing the relationship between lan the pressure regulating element in a pressure regulating unit and the controlled pressure; Figure 3 is a block diagram of a self-regulating pressure control valve in a first embodiment in accordance with the present invention finning; Figure 4 is a block diagram of a self-regulating pressure control valve in a second embodiment in accordance with the present invention finning; and Figure 5 is a block diagram of a self-regulating pressure control valve in a third embodiment in accordance with the present invention. finding.

Pig. 1 and 2 show a first embodiment of the application of the present invention on a pressure reducing valve 1. Med Referring to Fig. 1, the pressure reducing valve 1 has a pressure scaffold spring 2, one end of which is arranged on a spring seat 3 and the other end of which is arranged on a spring seat 6. The spring seats 3 and 6 are pressed against a diaphragm 4 and against the lower end (seen in Fig. 1) of a pressure regulating screw 8 via a ball 7. The pressure reducing the secondary pressure of the ring valve 1 is present in a pressure chamber 5, which is covered by the diaphragm 4. The position or position of the diaphragm 4 depends on of the pressure balance between the pressure applied to the diaphragm of the pressure setting spring_2_and the secondary pressure as rows inside pressure chamber 5. Because the membrane 4 secondary pressure control function is well known, a description thereof will not be given.

An outer thread 9 is formed on the lower part of the printing glazing screw or rod 8. The threaded lower end of the pressure regulating rod 8 is screwed into a fixed element, which is provided with an internal thread 10 in the central part of the element. One axial bore is provided in the upper part (seen in Fig. 1) of 466 321 10 15 20 25 30 35 the pressure regulating rod 8. An element 11, which retains balls 12, is inserted into the axial bore in the pressure control rod 8.

A splined shaft 13 is fitted in the axial bore in the pressure regulating rod 8 for engaging the balls 12. The shaft 13 is via a reduction gear 14 connected to an engine 15 output shoulder.

Because the pressure control rod engages the fixed the internal thread 10 of the element, the pressure regulating rod 8 is rotated by means of the shaft 13 with concomitant displacement downwards, then the motor 15 output shaft rotates in one direction. This compresses the pressure adjustment spring 2 via the spring seat 6 of the pressure control rod 8 to increase the set pressure. When the engine 15 the shaft, on the other hand, rotates in the opposite direction, it is rotated pressure regulating screw rod 8 in the opposite direction for movement upwards, whereby the compression of the pressure-adjusting spring 2 is reduced to reduce the set pressure.

The distance as the lower end of the pressure regulating rod 8 moved from a predetermined reference position (a position wherein the lower end of the pressure regulating rod 8 is in contact with the spring seat 6 via the ball 7 without any compression of the compression regulating spring), hereinafter referred to as "bar position", is proportional to the degree of compression or compressing the pressure adjusting spring 2 and thus against the set pressure, as shown in Fig. 2. The present finning effectively utilizes such a relationship between the displacement distance of the lower of the pressure regulating rod 8 end and the set pressure. 1 Referring to Fig. 3, which shows a first embodiment form of the present invention, it comprises self-regulating pressure control valve a pressure reducing valve 1, a pressure regulating unit 50 including the pressure regulating rod 8, a drive unit 52 including the motor 15, a pressure detection unit 54, a signal conversion unit 55, a control unit 56 including a computer which stores bar position data representing the functional the relationship between the bar position and the controlled pressure, and a pressure setting unit 58. In the first embodiment, the engine 15 and stepper motor.

The pressure sensor of the pressure detection unit 54 detects 10 15 20 25 30 35 466 52+ pressure pressure valve 1 secondary pressure and gives a pressure signal representing the secondary pressure of the signal conversion unit 55.

The signal conversion unit 55 then converts the pressure signal into one corresponding digital pressure signal and supplies it to the control unit 56 computer.

After receiving a signal representing a set pressure from the pressure setting unit 58, the computer calculates a corresponding to the set pressure for the pressure regulator the bar 8 on the basis of the bar position data previously stored in the computer and then supplies a pulse signal corresponding to the calculated bar position. drive to the drive unit 52 for operating the pressure control unit 50 so that the pressure regulating rod 8 is moved to it calculated bar position; the pressure relief valve 1 secondary consequently, pressure is adjusted immediately to the set pressure.

The angle of rotation of the output shaft of the stepper motor 15 is proportional against the number of pulses in the pulse signal, so that the position of the pressure The control bar 8 corresponds to the number of pulses in the pulse signal.

The pressure detection unit 54 detects the secondary pressure continuously or periodically, and the signal conversion unit 55 feeds digital signals to the controller 56 in a similar manner. Control unit computer 56 compares the detected secondary pressure with the set the pressure. Then it detected the deviation of the secondary pressure from the set pressure is within a predetermined range for the deviation, the control unit does not give any signal for influencing drive 52. When the deviation of the secondary pressure from the set pressure is greater than the limit value for it in advance determined area of the deviation, the computer calculates a distance for which the pressure regulating rod 8 needs to be moved to correct the deviation, which is based on the difference between lan the detected secondary pressure and the set pressure and bar position data stored in the computer. Then the computer provides one control signal representing the calculated correction distance for the secondary pressure correction, due to the influence of the drive unit so that it moves the pressure-adjusting screw 8 for fine-tuning the secondary pressure.

As an example, the following can be stated. Then the set pressure is 5 kg / cm2, the reference deviation range is + 0,1 kg / cm2 and the the secondary pressure is 4.5 kg / cmz, the computer calculates a 466 321 10 15 20 25 30 35 reaction distance corresponding to a pressure deviation of 0.5 kg / cm2 on basis of said bar position data for moving the pressure regulating rod 8 accordingly.

In connection with a more advanced pressure control can digital data representing the functional relationship between the set the pressure and the bar position, e.g. one predetermined correlation between the set pressure and the bar position re- presented by setting pressure at 1 kg / cmz intervals and de corresponding to the bar positions, are stored in the table in the means, the control and correction operation being performed on the basis of digital data in accordance with the predetermined correlation.

When a correction is made, digital data representing the previous bar position is to be replaced with the corrected ones data representing the new bar position for updating the table in said memory means.

For example, suppose that the bar positions S4 and S5 are stored in the computer's memory means corresponds to the set pressures, more precisely fixed set secondary pressures, of 4 and 5 kg / cm2 respectively. When the tile is set for a set pressure of 5 kg / cm2 using said pressure setting means, the motor drives the pressure regulating the bar to the corresponding bar position S5. When the reference range is +0.1 kg / cm2, the engine remains stopped as long as the the actual secondary pressure from the set pressure is within the reference deviation range_ Assume that the set pressure is 5 kg / cm2, that the reference the fold range is +0.1 kg / cm2 and that the prevailing secondary pressure is 4.5 kg / cm 2. The computer will then calculate a correction displacement S of the bar position corresponding to the deviation: 5.0 - 4.5 = 0.5 kg / cm 2 using the equation: S = (S5 - S4) x 0.5 / (5 - 4) The motor then drives the pressure regulating rod to provide it calculated the corrective displacement S for the bar position in the -to increase the secondary pressure from 4.5 kg / cm2 to 5.0 kg / cm2. The original bar position S5 which was stored in said memory device gan is then replaced by S5 + S.

When the same setting pressure is given to the control unit for ring of the controlled pressure to the same target pressure, after it the pressure regulating rod 8 has been moved from the previous closure 10 15 20 25 30 35 7 - 466 321 the position for changing the set pressure, the computer calculates the correct bar position to immediately adjust the secondary the pressure to the desired malt pressure.

Then the self-regulating pressure control valve's pressure control system salunda has been put in order, the pressure control system produces ideal control data even when the operating conditions of the pressure reducing valve change, said that the self-regulating pressure control valve has the ability to bring "håg" "svafnhantigneu The second embodiment illustrated in Figs. 1 and 4 is in the basis is similar to the first embodiment in terms of building and function. The second embodiment utilizes a ro- potentiometer to detect the pressure regulator the position of the rod 8 and a reversible motor instead of one stepper motor With form a pressure reducing valve 1, to drive the pressure regulating rod 8. Referring to Fig. 4, the second embodiment includes a pressure control unit 50, a drive unit 52, a pressure detector S4, a signal converter 55, a control unit 56, a pressure setting unit 58, a reduction gear 14 and a rotating potentiometer 20.

Referring to Fig. 1, the rotating potentiometer is Operatively coupled to one of the gears (not shown) in the reduction gear 14. The output voltage of the potentiometer 20 is proportional to against the movement of the pressure regulating rod 8 from the reference the cleaning position (a position in which the pressure regulating rod is in engagement with the pressure-adjusting spring 2 without compressing the latter), i.e. the rod position. The output voltage from the rotary consequently, the potentiometer 20 represents the rod position and thus the secondary pressure, ie the controlled pressure. In the second edition the embodiment is stored in the computer bar position data, which the functional relationship between the bar position is represented row of the output voltage from the rotating potentiometer 20 and kundärtryoket.

The rotary potentiometer 20 can be replaced by a linear one potentiometer or a differential transformer. Then a linear potentiometer is used, the arm of the potentiometer is arranged to move linearly together with the pressure regulating rod 8. Da en differential transformer is used, the core of the transformer is arranged to move linearly together with the pressure regulator the bar 8. 466 321 10 15 20 25 30 The control unit 56 continuously supplies a signal to the drive unit. 52, until the output of the rotary potentiometer 20, i.e. the bar position signal, corresponds to a signal which is supplied to the control unit 56 by means of the pressure setting unit 58.

Because the rest of the features are the same as those of the first embodiment, a description thereof will not be given for the purpose of recurrence of recurrence. _ The third embodiment, shown in Fig. 5, includes a pressure reducing valve 1, a reducing gear 14, a rotating one potentiometer 20, a pressure control unit 50, a drive unit S2, a control unit 70 and a pressure setting unit 72 which includes one potentiometer.

The controller 72 does not include a computer. The third The ring shape has the ability to control the secondary pressure in the simplest way on the basis of the relationship between the bar position and the secondary pressure, ie the controlled pressure. The rotary potentiometer 20, which is operatively connected to the reduction gear 14, provides a voltage signal representing a bar position corresponding to the secondary the pressure to the control unit 70, while the potentiometer in the pressure the setting unit 72 provides a voltage signal representing one set pressure to the control unit 72. The control unit 72 compares the voltage the signal representing the bar position and the voltage the signal representing the set pressure and emitting sends a control signal to the drive unit 52 to move the pressure regulating the rod, until the voltage signal given by it the rotating potentiometer 20 corresponds to the voltage signal which represents the set pressure.

The rotary potentiometer 20 can be replaced by a linear one potentiometer or a differential transformer, as mentioned in in connection with the description of the second embodiment. ' Although the invention has been described with reference to preferred embodiments with a certain degree of peculiarity, it should be It is understood that many changes and variations are possible within the framework for the invention.

Claims (6)

e-L 10 15 20 25 30 35 40 466 3251, Automatic pressure control valve device comprising a pressure control valve (1); pressure regulating means (50) coupled to the pressure control valve (1) for regulating the pressure controlled by the pressure control valve (1) by means of the position of a pressure regulating element (8); pressure setting means (58, 72) for setting a mill pressure; and drive means (52) for driving said pressure regulating means (50) for positioning the pressure regulating element (8); characterized by a control unit (55, 70) for controlling said drive means (52) on the basis of the target pressure set by said pressure setting means (58, 72) and a predetermined relationship between the position of the pressure regulating element (8) and the actual controlled pressure, in order to move the pressure regulating element (8) for adjusting the actual pressure. Valve device according to claim 1, characterized in that said control unit (56) comprises memory means, which store control data representing the predetermined relationship between the position of the pressure regulating element (8) and the actual controlled pressure, and computer means for calculating a position, in which said pressure regulating element (8) is to be brought, on the basis of said stored control data and data concerning the target pressure set by means of said pressure setting means (58, 72); that position detecting means are arranged to detect the position of the pressure regulating element (8); and said control unit (55) controls said drive means (52) for driving said pressure control means (50), until the detection signal of said position detecting means (20) corresponds to a signal representing the calculated position of the pressure regulating element (8). Valve device according to claim 1, characterized in that said control unit (56) includes computer means which store control data representing the predetermined functional relationship between the position of the pressure regulating element (8) in said pressure regulating means (50) and the actual controlled pressure, wherein said drive means (52) includes a stepping motor (15) and said computer means are arranged to calculate on the basis of a set pressure signal obtained from said pressure setting means (58) a pulse signal, the number of which pulses correspond to a position in which the pressure regulating element (8) is to be brought, and supply the pulse signal to the stepper motor (15) for adjusting the controlled pressure to the set pressure. Valve device according to claim 2 or 3, characterized by means (54) for detecting the actual controlled pressure, wherein the control unit (56) is arranged to continuously or periodically compare the detection signal emitted by said detection means (54) and the set pressure signal as is provided by said pressure setting means (S8) for determining the deviation of the controlled pressure from the set pressure, and said computer means are arranged that if there is a significant deviation of the controlled pressure from the set pressure, calculate a correction distance which the pressure regulating element ( 8) in said pressure control means (50) need to be moved from the position occupied by the element, on the basis of the deviation and control data stored in the control unit (56) in order to correct the controlled pressure, so that the controlled pressure corresponds to the set pressure. Valve device according to claim 4, characterized in that the control unit (56) is arranged to store the position of the pressure regulating element (8) in said pressure control means (50), determined by the control unit (56) on the basis of the difference between the signal representing the detected controlled pressure and the signal representing the set pressure, as a new correct position of the pressure regulating element (8) in said pressure regulating means (50). Valve device according to claim 1, characterized in that said control unit (70) is arranged to control said drive means (52) for operation thereof, until a detection signal corresponding to the position of the pressure regulating element (8) in said pressure regulating means (50) , detected by a potentiometer or similar position detecting means, corresponds to a signal representing a set pressure, which signal is given by a potentiometer or the like in said pressure setting means (72).