WO2017216737A1 - A method and a system for controlling an actuator of a ram of a press - Google Patents

Abstract

The system for controlling an actuator (10; 115) of a ram of a press comprises: a motor group (1; 101) that actuates a pumping group (2; 102); a ram that is hydraulically connected by a hydraulic system with the motor group (1; 101) and/or pumping group (2; 102) and that is movably actuated between a first stroke of approach to a piece to be worked, a second working stroke of the piece to be worked, and a third return stroke from a worked piece; the method for actuating the presses comprises controlling the approach stroke and/or the working stroke and/or the return stroke by the motor group (1; 101) connected with the pumping group (2; 102).

Description

"A METHOD AND A SYSTEM FOR CONTROLLING AN ACTUATOR OF A RAM

OF A PRESS"

DESCRIPTION

Field of application

The invention relates to a method and a system for controlling an actuator of a ram of a press, used for working pieces to be worked, to make the working cycle and the structure of the press more economical.

State of the art

A known hydraulic circuit installed on a press to actuate its ram comprises a series of components that allow the ram, in order to perform workings of pieces such as punching or folding, to carry out a quick stroke of approach to the piece, followed by a slower extra-stroke to perform working, and a final return stroke in the rest position raised by the piece.

Typically, according to the known state of the art, presses are divided in two types, namely presses that have a ram having a considerable self-weight, which affects its general operation, and presses that have rams with a self-weight that is considered light and which scarcely affect the general operation.

In both types of presses, basically two types of circuits are used to move the ram. In a first known construction scheme of the hydraulic circuit that actuates the ram, an asynchronous motor is provided, which actuates a constant-flow pump, which, in turn, feeds an accumulator acting as a tank of the pumped oil.

At the accumulator exit a servo-valve is arranged that, in turn, is hydraulically connected with the push chamber of the cylinder the piston of which actuates the ram.

The movement of the piston, in this case, is controlled by the servo-valve.

In a second known construction scheme of the hydraulic circuit that actuates the ram of the press, an asynchronous motor is provided that, however, in this case functions with a fixed number of revolutions and is connected with a variable-flow pump, which, in turn, feeds the push chamber of the cylinder the piston of which actuates the ram.

The movement of the piston of the cylinder, in this case, is controlled by the servo-valve mounted on the pump that controls the flow-rate and the working pressure.

For over a five-year period a new system has been adopted that provides the use of a servo-pump, composed of a brushless motor combined with a four-quadrant pump, normally with internal gears or with pistons, that, besides controlling the speed and the direction of the actuator that moves the ram, with the use of a measurement system determines its position and with the use of a pressure transducer can limit its load.

In this hydraulic system, the pumps used, either of the type with internal gears or of the type with axial pistons, are in both cases - as already said - of the four-quadrant type- In all cases cited, to reverse the direction of motion of the ram and to perform the workings requested, pumps must be able to reverse their direction of rotation as quickly as possible, typically in some milliseconds, to allow the performance of the working cycles of the pieces.

This state of the art has some drawbacks.

A first drawback consists in the fact that known pumps are typically subject to cavitation phenomena during the extremely quick reversals of motion, while they remain without oil and, consequently, without lubrication, causing the interruption of the hydrostatic support action of the rotating parts.

This causes an immediate damage to the pumps.

A second drawback consists in the fact that pumps of the four-quadrant type, which are renownedly expensive and have a limited efficiency, are generally mounted in these hydraulic circuits, which, therefore, makes also the manufacturing and the maintenance of the presses that use them proportionally expensive.

A further drawback consists in the fact that with the use of known presses it is very difficult to establish some special working parameters exactly, such as, for instance, the verification and the possible successive correction of the folding angle of a piece during its working, i.e. it is very difficult to move the ram at a low speed with centesimal displacements in both directions.

Presentation of the invention

An object of the invention is to improve the known state of the art.

Another object of the invention is to provide a method and a system for controlling an actuator of a ram of a press that allows to reduce general manufacturing costs.

A further object of the invention is to achieve a method and a system for controlling an actuator of a ram of a press that has a structure that is simplified and, consequently, economical as compared to the state of the art.

According to an aspect of the invention, there is provided a method for controlling an actuator of a ram of a press in accordance with the features of claim 1.

According to another aspect of the invention, there is provided a system for controlling an actuator of a ram of a press in accordance with the features of claim 5.

Further aspects of the invention are indicated in the dependent claims.

The invention allows to achieve the following advantages:

- limiting the manufacturing costs of presses for working pieces to be worked;

- avoiding damages to the press components, in particular to the pumps feeding the fluid under pressure;

- accurately performing and controlling special workings of the pieces to be worked, such as, for instance, a folding angle.

Brief description of the drawings

Further features and advantages of the invention will be clearer from the detailed description of a preferred, but not exclusive, form of embodiment of a method and a system for controlling an actuator of a ram of a press, illustrated by way of a non- limiting example in the hydraulic diagrams shown in the attached drawings, in which:

FIG. 1 is a view of a diagram of a hydraulic system according to the invention, in a configuration of a ram of a press provided with a considerable self-weight and stationary at an upper dead center;

FIG. 2 is a view of the hydraulic system of Figure 1, in a configuration of quick descent of the ram using self-weight;

FIG. 3 is a view of the hydraulic system of Figure 1, in a configuration of slowed down descent of the ram in the direction of a piece to be worked;

FIG. 4 is a view of the hydraulic system of Figure 1, in a working configuration of a piece to be worked;

FIG. 5 is a view of the hydraulic system of Figure 1, in a configuration of quick decompression;

FIG. 6 is a view of the hydraulic system of Figure 1, in a configuration of controlled decompression;

FIG. 7 is a view of the hydraulic system of Figure 1, in a configuration of return of the ram to the upper dead center; FIG. 8 is a view of a diagram of a hydraulic system according to the invention, in a configuration of a ram of a press provided with a self-weight that is not considerable, in a configuration of loading an accumulator inserted in the system;

FIG. 9 is the diagram of Figure 8 in a condition of stop of the ram to an upper dead center;

FIG. 10 is the diagram of Figure 8 in a condition of quick descent, of working and of maintenance of the action of the ram;

FIG. 11 is the diagram of Figure 8 in a condition of return of the ram toward the upper dead center.

Detailed description of preferred examples of embodiment.

With reference to Figures from 1 to 7, here below the components of a hydraulic circuit according to the invention are indicated, in a first possible form of embodiment, particularly suitable to be used for the operation of a press in which the ram has a considerable self-weight able to affect the movements of the latter:

1 = brushless motor;

2 = constant-flow pump;

3 = outlet;

4 = pressure transducer;

5 = first electro-distributor, hereinafter briefly ED5;

6 = second electro-distributor, hereinafter briefly ED6;

7 = third electro-distributor, hereinafter briefly ED7;

8 = outlet;

9 = pressure reducer;

10 = actuating cylinder of the ram;

11 = unidirectional valve;

12 = upper push chamber of the cylinder;

13 = lower push chamber of the cylinder;

14 = fourth electro-distributor, hereinafter briefly ED 14;

15 = balancing valve;

16 = safety valve on the lower chamber side;

17 = maximum pressure and quick decompression valve;

18 = outlet cartridge;

19 = tight pilot electro-valve; 20 = pilot of the maximum pressure valve;

21 = automatic air vent valve;

22 = metering device.

With reference to Figure 1, a condition is observed in which the actuating cylinder 10 that moves the ram of a press (both not illustrated because they are known to the person of skill in the art) is stationary at the upper dead center, hereinafter shortly UDC.

In this condition, both the brushless motor 1 (hereinafter shortly motor 1) and the two-quadrant pump 2 (hereinafter shortly pump 2) are standing still and in the lower chamber 13 there is enough oil under pressure to keep the actuating cylinder 10 raised to the UDC, overcoming the self-weight "P" of the ram of the press.

In the hydraulic line (x) there is also residual oil under pressure, which, however, does not cause any displacement, because ED6 and ED 14 are in the respective closed positions "6C" and " 14C".

With reference to Figure 2, a condition of quick approach of the ram to a piece to be worked that is positioned on a working plane (not shown) can be observed, where the ram is actuated by the actuating cylinder 10 in an active working stroke.

In this condition, ED6 switches to the open position "6A" connecting the hydraulic line (x) with the pump 2 that, pressed by the hydraulic pressure caused by the self-weight "P" of the actuating cylinder 10 and of the ram coupled therewith, performs a passive counter-rotation in a direction of rotation, in the specific case indicated by the left arrow "SX", while the motor 1 performs the function of controlling the passive counter-rotation speed of the pump 2, acting as a regulator of the same.

In this condition also ED14 switches to the open position "14A", putting the lower chamber 13 in communication with the outlet 3, through the hydraulic line (z), following the flow arrows "Fl".

It shall be observed that in this condition oil under pressure flows through the metering device 22 that slows down its outflow depending on a flow cross-section having a predetermined width.

With reference to Figure 3, a condition of slow-down of the descent of the ram and of the actuating cylinder 10 can be observed.

In this condition, ED6 switches again to its closed position "6C", interrupting the direct connection with the lower chamber 13, while ED 14 remains in the open position " 14A", where the lower chamber 13 is kept hydraulically connected with the outlet 3 and the outflow of the oil under pressure present in the lower chamber 13 is slowed down exclusively by the metering device 22, even if the pump 2 continues to rotate in the counter-rotation "SX", controlled in the rotation by the motor 1 with which it is connected.

With reference to Figure 4 a working condition of the ram and of the actuating cylinder 10 with which it is coupled can be observed.

In this condition, it can be noticed that ED5 switches to the crossed position "51" while ED14 switches to its closed position "14C", interrupting the connection of the lower chamber 13 with the outlet 3.

The motor 1 actuates the pump 2, which reverses its direction of rotation, passing from a counter-rotation "SX" to an active pumping rotation indicated by the arrow "DX".

In this condition, the oil under pressure feeds (arrows F2) the upper chamber 12 through the hydraulic line (x), moving the cylinder toward the piece to be worked and performing the working requested.

With reference to Figure 5, a condition of beginning of decompression following the phase of working of a piece can be noticed.

In this condition, it is noticed that ED5 remains in its crossed position "51" while the shutter 18 opens, putting the upper chamber 12 in communication with the outlet 3 through the hydraulic line (x), following the outflow indicated with the arrows "F3".

As can be noticed from Figure 5, in this condition both the motor 1 and the pump 2 are standing still.

With reference to Figure 6, a condition of decompression can be noticed, which is however more controlled as compared to the condition illustrated in Figure 5.

In this condition, the shutter 18 remains closed, interrupting the direct connection between the upper chamber 12 and the outlet 3.

The oil under pressure present in the upper chamber 12, therefore, flows out through the hydraulic line (x) following the flow indicated again by the arrows "F3", toward the pump 2, putting it in counter-rotation "SX", with a rotation speed controlled by the motor 1 that, typically, performs also in this condition the function of speed controller.

From the pump 2 the oil flows out then in the outlet 3. With reference to Figure 7, a condition of return of the actuating cylinder 10 to the UDC can be noticed.

In this condition, it is noticed that ED7 switches and passes from the open position "7A" to its crossed position "71" and the suction valve 11 opens, connecting the upper chamber 12 with a tank 11A put in connection with the chamber and allowing depressurization of the upper chamber 12.

In this condition, ED5 switches to its open position "5A" connecting the pump 2 with the lower chamber 13 through the hydraulic line "X and ED6 positioned in the closed configuration unidirectionally "6C".

In this condition, the motor 1 actuates the pump 2, which rotates in an active rotation and feeds with oil under pressure the lower chamber 13 raising the actuating cylinder 10 until it reaches its UDC.

With reference to Figures from 8 to 11, here below the components of a hydraulic circuit according to the invention are indicated, in a second possible form of embodiment, particularly suitable to be used for the operation of a press in which the ram has a self-weight that is not particularly considerable and that, therefore, is not able to affect its movements remarkably, in particular, but not only, in the phase of movement toward a piece to be worked.

101 = brushless motor;

102 = constant-flow pump;

103 = outlet;

104 = maximum pressure valve;

105 = accumulator;

106 = feeding unit of the accumulator 105;

107 = unidirectional valve of 106;

108 = pressure reducer of 106;

109 = cartridge electro-valve of 106;

110 = PED safety valve of 105;

111 = cock/outlet electro-valve of 105;

112 = pressure transducers;

113 = cylinder chamber on the rod side;

114 = cylinder chamber on the head side;

115 = actuating cylinder of the ram; 116 = shut-off valve.

With reference to figure 8, a load condition of the accumulator 105 is noticed, in which the pump 102 is actuated by the motor 101 and rotates in an active rotation in the direction indicated by the arrow "DX".

In this condition the ram of the press is stationary and the oil under pressure, following the hydraulic line (x), reaches the accumulator 105, passing through the feeding unit 106 in which the electrovalve 109 is in the open position 109A.

The oil under pressure reaches also the chamber 113 on the rod side of the cylinder 115, which, however, remains stationary, since the shut-off valve 116 is positioned in the closed condition 1161, preventing drainage of oil from the chamber 114 on the head side of the cylinder 115.

When one of the pressure transducers 112 placed on the hydraulic line (x) detects that a programmed pressure value has been reached, at which value the pressure reducer 108 was set in advance, it interrupts the operation of the motor 101 and, consequently, of the pump 102.

With reference to Figure 9, a static condition of the ram is observed, because the cylinder 115 is kept at the UDC after the completion of the loading phase of the accumulator 105.

In this condition, the motor 101 stands still, just like the pump 102, and both are not subject to load.

The oil under pressure that is present in the chamber 113 and in the accumulator 105 from the previous phase of filling keeps the cylinder 115 at the UDC flowing in the hydraulic line indicated with (o).

In this condition, the press punch is raised in relation to the die and an operator can position a piece to be worked under the ram, between the punch and the die, or can carry out other maintenance operations.

With reference to Figure 10, a condition is observed that can be alternatively of quick descent of the ram, or a working condition, or a condition of so-called maintenance, this latter being a condition in which the ram remains stationary in a position of work completed and waits, for instance, for the yield of the material with which a piece is manufactured during the working phase, or for the cooling down of a piece just manufactured.

In detail, it is noticed that the shut- off valve 116 is switched to the open position 116A, connecting the pump 102 that rotates in an active rotation "DX", actuated by the motor 101, delivering oil under pressure to the chamber 114 following the arrows F2.

It must be observed that in this second form of embodiment of the hydraulic circuit according to the invention, the self-weight of the ram, as already reminded before, is substantially uninfluential with respect to the movement of descent of the cylinder 115, which is moved, therefore, by the push of oil under pressure that reaches the chamber 114 on the push side of the cylinder 115 through the line (x): the movement of the cylinder 115 is opposed in the phase of descent by the pressure of the oil that is present in the chamber 113 on the rod side and that in this condition flows out towards the accumulator 105 along the hydraulic line (o), according to the direction of the arrow F4.

The descent of the actuating cylinder 105 is controlled by a known signaling system of its position and, when it reaches the lower limit position that corresponds to the final working position of a piece to be worked, the phase of keeping mentioned before is activated, in which the actuating cylinder 105 is kept stationary until the material in which the piece to be worked is manufactured has stabilized or cooled down: this is the case, for instance, of a folding work of a sheet metal piece that, after the active phase of proper folding, requires a waiting phase, to allow the folded sheet metal to stabilize its own condition of internal stress caused by folding, or to cool the formed piece, for instance in case of forming pieces manufactured in glass.

In the condition illustrated in Figure 10, the movement downwards of the cylinder 115 is controlled by the difference of the pressures of the oil volumes that are present in the chambers 114 and 113, this latter in connection with the accumulator 105 that in this condition behaves like a compressible hydraulic spring.

With reference to Figure 10, a condition of return of the cylinder 115 toward the upper dead center (UDC) is observed after the completion of a working phase.

In this condition, the shut-off valve 116 is kept in the open configuration 116A connecting, through the hydraulic line (#), the chamber 114 with the outlet 103, through the pump 102.

The latter is brought in passive counter-rotation indicated by the arrow "SX" by the flow of oil that flows out from the chamber 114.

The counter-rotation "SX" is contrary to the active rotation "DX" and the counter-rotation speed is controlled by the motor 101 that, in practice, acts as a brake for the rotation of the pump 102 that becomes a control element of the outflow of oil through the hydraulic line (#) and, consequently, of the speed of reascent of the cylinder 115 toward the UDC.

In this condition, the accumulator 105 feeds oil under pressure into the chamber

113 on the rod side through the line (o) according to the arrow F5, providing the necessary push for the return of the cylinder 115, and the unidirectional valve 107 prevents oil under pressure that flows out from the accumulator 105 from flowing directly towards the outlet 103, i.e. by-passing the cylinder 115.

The pressure reducer 108 allows both to change the pressure inside the accumulator 105 and to discharge a small quantity of oil through its drainage duct.

When the cylinder 115 moves down, the oil that is present in the chamber 113 is pushed into the accumulator 105, causing a pressure increase inside the latter, previously established by the pressure reducer 108.

This pressure increase causes a drainage of small quantities of oil from the pressure reducer (of the order of 2-4 liters per minute, considering that the drainage activates in the cycle, only in the phase of descent of the cylinder) that is restored when the cylinder 115 carries out a reascent stroke.

During this phase, pressure inside the accumulator 105 decreases down to a value lower than the one determined by the pressure regulator 108, and the oil present in the inside is constantly refilled by a supply of additional fresh oil.

It must be noticed that, according to the invention, the use of the accumulator 105 with the function of hydraulic spring is also possible in a press in which the self- weight of the ram (or of the rammer) is considerable.

In this case, the presence of the accumulator 105, which performs the function of a hydraulic spring having a variable force, since it is arranged to contain oil with an adjustable pressure, on the one side allows for the use of two-quadrant pumps and on the other side improves the repeatability at the UDC in the presses having rams with a considerable weight.

In a folding press, the action of the accumulator 105, besides improving the positioning accuracy of the ram/rammer, allows to control the displacement speeds thereof and with the counter-rotation of the brushless motor and of the pump, allows the rammer to move micrometrically in both directions, i.e. to float, a condition that, with the use of four-quadrant pumps, is difficult to be achieved.

In a folding press, the presence of the accumulator 105 allows both to obtain an improvement of the final position, and to control the speed of the ram causing it to move micrometrically in both directions.

In practice, it has been ascertained that the invention achieves the objectives that it set itself.

The invention as it was conceived is susceptible to modifications and variants, all of them falling within the inventive idea.

Further to that, all the details can be replaced by other elements that are technically equivalent.

In the practical execution, the materials used as well as the forms and dimensions can be any, according to the requirements, without for this departing from the scope of protection of the following claims.

Claims

1. A control method for controlling an actuator (10; 115) for actuating a ram of a press, comprising:

- actuating a motor group (1; 101) with which a pumping group (2; 102) fluidly connected to said actuator (10; 115) by a fluid-dynamic circuit and having an active rotation (DX) and a passive counter-rotation (SX) is associated;

- reciprocating said actuator (10; 115) between an active working stroke during said active rotation (DX) and a return stroke during said counter-rotation (SX); characterized in that it comprises controlling by said motor group and pumping group (1, 2; 101, 102) at least one of said active stroke and/or return stroke during at least one of said active rotation (DX) and/or said counter-rotation (SX).

2. The method as claimed in claim 1, wherein said controlling comprises controlling an active working speed of said active stroke and/or a return speed of said return stroke.

3. The method as claimed in claim 1, wherein said pumping group comprises at least a 2-quadrant pump (2; 102) and said motor group comprises a brushless motor (1;

101) .

4. The method as claimed in claim 1, wherein said active stroke comprises alternatively punching, folding, molding pieces to be worked.

5. A system for controlling an actuator (10; 115) of a ram of a press, comprising:

- a motor group (1; 101);

- a pumping group (2; 102) associated with said motor group (1; 101) and designed to pump a feeding fluid;

- an actuator group (10; 115) of said ram that reciprocates at least in an active working stroke or in a passive return stroke;

- a connecting and conveying fluid-dynamic circuit which connects said pumping group (2; 102) with said actuator (10; 115) and conveys a feeding fluid of the latter; characterized in that it comprises control means of at least said active working stroke or of said passive return stroke consisting in said motor group (1; 101) associated with said pumping group (2; 102).

6. The system as claimed in claim 5, wherein said motor group comprises a brushless motor (1; 101) and said pumping group comprises a 2-quadrant pump (2;

102) .