RU2764536C1 - Method for controlling the movable traverse of a hydraulic press - Google Patents

Abstract

FIELD: forging equipment.

SUBSTANCE: invention relates to forging and pressing equipment and can be used in hydraulic press control systems. After completion of the working stroke of the traverse 11 of the hydraulic press, the supply of working fluid to the working cavities of the working hydraulic cylinders 1, 2 of the traverse stops. The working cavities of the return hydraulic cylinders 3, 4 are separated from the hydraulic tank 10. Then the working cavities of the working hydraulic cylinders are unloaded from high pressure in two stages by connecting them at the first stage with the working cavities of the return hydraulic cylinders 3, 4 until the pressure values in these cavities are aligned with a given error. At the second stage, the working cavities of the working hydraulic cylinders after disconnecting from the working cavities of the return hydraulic cylinders 3, 4 are connected to the hydraulic tank 10. The reverse course of the traverse is carried out.

EFFECT: as a result, an increase in the number of strokes of the press traverse per unit of time is ensured by combining in time the first stage of unloading the working cavities of the working hydraulic cylinders after the end of the working stroke and the stage of using part of the potential energy accumulated during the working stroke of the traverse.

1 cl, 1 dwg

Description

The invention relates to the field of forging and pressing equipment, and in particular to methods for controlling the movable traverse of hydraulic presses, and can be used to modernize existing and create new control systems for these units.

A known method of controlling the movable traverse of a hydraulic press, according to which, after the completion of the working stroke of the traverse, the supply of working fluid to the working cavities of the working hydraulic cylinders of the traverse is stopped, the working cavities of the return hydraulic cylinders of the traverse are separated from the hydraulic tank, the working cavities of the working hydraulic cylinders of the traverse are unloaded from high pressure by connecting them with hydraulic tank and carry out the reverse motion of the traverse [1].

When using this method of controlling the movable traverse, the potential energy accumulated during the working stroke of the traverse due to elastic deformations of the working fluid and metal structures (in particular, columns) of the press, in the process of unloading the working hydraulic cylinders of the traverse from high pressure after connecting them to the hydraulic tank, is converted into thermal energy ( and is eventually lost, dissipating into the environment), which is a disadvantage of the method.

Closest to the claimed technical solution is adopted as a prototype method of controlling the movable traverse of a hydraulic press, according to which, after the completion of the working stroke, the traverse stops supplying the working fluid to the working cavities of the working hydraulic cylinders of the traverse, the working cavities of the return hydraulic cylinders of the traverse are separated from the hydraulic tank, the working cavities of the workers hydraulic cylinders of the traverse are unloaded from high pressure in two stages by connecting them at the first stage with the device for receiving the working fluid, and at the second stage by connecting them to the hydraulic tank after disconnecting from the device for receiving the working fluid, and the reverse stroke of the traverse is carried out [2]. According to this method, a pneumohydraulic accumulator is used as a device for receiving a working fluid. In the process of unloading the working hydraulic cylinders from pressure, some of the potential energy accumulated during the working stroke of the traverse is accumulated due to elastic deformations of the working fluid and metal structures (in particular, “columns) of the press” by means of gas (as a result of its compression) in a pneumohydraulic accumulator. The energy of the compressed gas contained in the pneumohydraulic accumulator is further used to perform useful work when performing subsequent technological operations to change the position of the press's movable traverse.

The conversion of the potential energy accumulated during the working stroke of the traverse due to elastic deformations of the liquid and metal structures of the press, first into the energy of the compressed gas, and then the conversion of the energy of the compressed gas into the mechanical energy of the liquid is accompanied by additional losses of the accumulated energy during each conversion, which reduces the potential share of its use when performing subsequent technological operations to change the position of the movable traverse of the press.

In addition, these stages of energy conversion are carried out for different periods of time, as a result of which the duration of the working cycle of moving the movable traverse of the press turns out to be greater than its potentially possible minimum value, other things being equal, which reduces the speed of the press (the number of moves of the movable traverse per unit time) and is disadvantage of the known control method.

The technical problem solved by the invention is the creation of a method for controlling the movable traverse of a hydraulic press, which provides an increase in the speed of the press (the number of moves of the movable traverse of the press per unit time) due to the coincidence in time of the first stage of unloading the working cavities of the working hydraulic cylinders of the traverse from high pressure after the end of the working stroke of the traverse and the stage of using a part of the potential energy accumulated during the working stroke of the traverse due to elastic deformations of the liquid and metal structures of the press, to perform the reverse stroke of the traverse.

To solve this problem, in a known method for controlling a movable traverse of a hydraulic press, according to which, after the completion of the working stroke, the traverses stop supplying the working fluid to the working cavities of the working hydraulic cylinders of the traverse, the working cavities of the return hydraulic cylinders of the traverse are separated from the hydraulic tank, the working cavities of the working hydraulic cylinders of the traverse in two stages they are unloaded from high pressure by connecting them at the first stage with the device for receiving the working fluid, and at the second stage by connecting them to the hydraulic tank after disconnecting from the device for receiving the working fluid, and the traverse is reversed, according to the invention, at the first stage, the working cavities of the working hydraulic cylinders of the movable traverse are unloaded from high pressure, the working cavities of the return hydraulic cylinders are used as a device for receiving the working fluid, while the working cavities of the working and return hydraulic cylinders are separated after alignment with a given error in pressure values ia in the indicated cavities.

The use of the working cavities of the return hydraulic cylinders at the first stage of unloading the working cavities of the working hydraulic cylinders of the movable traverse from high pressure as a device for receiving the working fluid and the separation of the working cavities of the working and return hydraulic cylinders after alignment with a given error in the pressure values in these cavities provides, other things being equal, a reduction in the duration of the working of the cycle of movement of the movable traverse of the press and, accordingly, an increase in the speed of the press (the number of moves of the movable traverse per unit time), due to the combination in time of the first stage of unloading the working cavities of the working hydraulic cylinders of the traverse from high pressure after the end of the working stroke of the traverse and the stage of using part of the potential energy accumulated during the working stroke of the traverse due to elastic deformations of the liquid and metal structures of the press, to perform the reverse stroke of the traverse.

The essence of the invention is illustrated by the drawing, which shows one of the possible embodiments of the schematic diagram of the electro-hydraulic drive of the movable traverse of the hydraulic press for implementing the proposed control method.

The electro-hydraulic drive of the movable traverse of the hydraulic press includes plunger working hydraulic cylinders 1, 2, plunger return hydraulic cylinders 3, 4, hydraulic distributors 5, 6 for controlling the working hydraulic cylinders 1, 2 and return 3, 4, respectively, pressure hydraulic line 7 connected to the pressure source channel supply of the working fluid 8 and the filling and drain drain line 9 connected to the filling hydraulic tank 10.

The plungers of the hydraulic cylinders 1, 2, 3, 4 are connected to the movable traverse 11 of the press.

The electro-hydraulic drive of the movable traverse, according to the type of source of supply of the working fluid 8, can be pumping or pump-accumulator.

In the case of a pump drive, the working fluid supply source 8 is a pumping unit, which includes several positive displacement pumps (both adjustable and non-regulated), each of which is equipped with an individual electrically controlled safety valve (with the ability to transfer the pump from pressure relief mode to the mode of operation under load and vice versa) and is connected by its pressure channel through an individual check valve to the pressure channel of the supply source 8 (the structure of the working fluid supply source 8 is not shown in the drawing). In this case, the total nominal flow of the pumps that are part of the pumping unit corresponds to the flow rate of the working fluid required to move the movable crosshead 11 at the maximum speed set for the working stroke.

In the case of a pump-and-accumulator drive, the source of supply of the working fluid 8 is a combination of a pumping unit, which includes several positive displacement pumps (usually unregulated), each of which is equipped with an individual electrically controlled safety valve (with the possibility of transferring the pump from unloading mode from pressure on the operating mode under load and vice versa) and is connected by its pressure channel through an individual check valve to the pressure channel of the pumping unit, and a pneumohydraulic accumulator, the liquid cavity of which is connected to the pressure channel of the pumping unit by means of an automatically controlled two-line on-off valve of the one-way hydraulic lock type, through which, when In the absence of a control signal, the movement of the working fluid is possible only in the direction of the accumulator. In this case, the total nominal flow of the pumps that are part of the pumping unit corresponds to the average flow rate of the working fluid for the working cycle of moving the movable traverse of the press, calculated on the basis of the sum of the volumes of liquid required to be supplied to the working hydraulic cylinders during the working stroke of the traverse and to the return hydraulic cylinders during reverse stroke of the traverse (at the maximum values of the working and reverse strokes of the traverse during the working cycle). The pressure channel of the pumping unit is connected to the pressure channel of the working fluid supply source 8 by means of a two-line on-off shut-off valve with electrohydraulic control and a normally closed flow area (the structure of the pump source of working fluid supply 8 is not shown in the drawing).

The composition of the valve 5 includes pressure 12 and filling-drain 13 valves. The working cavities of the hydraulic cylinders 1, 2 are connected to each other by means of a pressure valve 12 with a pressure hydraulic line 7, and through a filling-drain valve 13 - with a filling-draining hydraulic line 9.

The composition of the valve 6 includes pressure 14 and drain 15 valves. The working cavities of the return hydraulic cylinders 3, 4 are connected to each other by means of a pressure valve 14 with a pressure hydraulic line 7, and through a drain valve 15 - with a filling-draining hydraulic line 9.

The working cavities of the return hydraulic cylinders 3, 4 are connected to the working cavities of the working hydraulic cylinders 1,2 by means of an additional two-line on-off valve 16 with a normally closed flow area.

The above valves: 12, 16 - have individual electro-hydraulic control. In the drawing, these valves are shown in a state where their flow area is closed.

For remote control of the pressure in the working cavities of the working hydraulic cylinders 1, 2, a pressure sensor 17 is attached to them.

For remote control of the pressure in the working cavities of the return hydraulic cylinders 3, 4, a pressure sensor 18 is attached to them.

The press is controlled by means of an electronic control system (the control system of the press is not shown in the drawing), to which all electrically controlled hydraulic devices and sensors that are part of the considered electro-hydraulic drive are connected.

The proposed method for controlling the movable traverse of a hydraulic press is implemented as follows.

In the initial state of the hydraulic drive, the flow sections of the valves 12, 14, 15 and the valve 16, if it is part of the hydraulic drive, are closed, and the flow section of the filling and drain valve 13 is open. At the same time, the working cavities of the return hydraulic cylinders 3, 4 are locked, the working cavities of the working hydraulic cylinders 1, 2 are separated from the pressure hydraulic line 7 of the press, and the movable traverse 11 is in a fixed position, and the pressure in the working cavities of the working hydraulic cylinders 1, 2 is determined by the pressure in the filling hydraulic tank 10 and mutual arrangement of the hydraulic tank 10 and hydraulic cylinders 1, 2.

The working cycle of moving the movable traverse 11 begins with the implementation of the approximation stroke, that is, the idling of the traverse in the direction of the workpiece to be deformed (the workpiece is not shown in the drawing). To carry out the approach of the movable traverse 11, the flow section of the drain valve 15 of the return hydraulic cylinders 3, 4 is opened.

To carry out the working stroke after the entry of the tool (the tool is not shown in the drawing), fixed on the movable crosshead 11, the flow section of the filling and drain valve 13 is closed in contact with the workpiece and the flow section of the pressure valve 12 of the working hydraulic cylinders 1, 2 is opened. pumping hydraulic drive, all or part of the pumps that are part of the source of supply of the working fluid 8, depending on the required speed of the traverse 11 during the execution of the working stroke, are transferred from the unloading mode from pressure to the operating mode under load. It should be noted that in the case of a hydraulic pump drive, all pumps that are part of the working fluid supply source 8, with the traverse 11 stopped, as well as during the approach and unloading stroke of the working hydraulic cylinders 1, 2 from pressure, operate in the unloading mode from pressure. In the case of a pump-accumulator hydraulic drive, the transfer of pumps from the mode of unloading from pressure to the mode of operation under load and vice versa is carried out automatically depending on the pressure and/or the level of the working fluid in the liquid cavity of the pneumohydraulic accumulator, which is part of the source of supply of the working fluid 8.

After the completion of the working stroke, the traverses 11 close the passage section of the pressure valve 12 of the working hydraulic cylinders 1, 2, thereby stopping the supply of working fluid to the working cavities of these hydraulic cylinders, and close the passage section of the drain valve 15 of the return hydraulic cylinders 3, 4, thereby separating the working cavities of the latter from hydraulic tank 10, after which the working cavities of the working hydraulic cylinders 1, 2 of the traverse are unloaded from high pressure in two stages by connecting them at the first stage with the working cavities of the return hydraulic cylinders 3, 4, for which the flow section of the valve 16 is opened. As a result, the working fluid flows from the working cavities of the working hydraulic cylinders 1, 2 to the working cavities of the return hydraulic cylinders 3, 4 with a simultaneous decrease in pressure in the working hydraulic cylinders 1, 2 and an increase in pressure in the return hydraulic cylinders 3, 4. Thus, at the first stage of unloading the working hydraulic cylinders 1, 2 from pressure immediately there is a transformation of some part of the potential energy accumulated during the working stroke of the traverse due to elastic deformations of the working fluid and metal structures (in particular, columns) of the press, into the energy of the fluid used later for the reverse stroke of the traverse.

After equalizing with a given error the pressure values in the working cavities of the working 1, 2 and return 3, 4 hydraulic cylinders (control of these pressure values is carried out on the basis of the signals of pressure sensors 17 and 18, respectively), these cavities are separated by closing the flow section of the valve 16 and for the implementation of the second stage unloading the working cavities of the working hydraulic cylinders 1, 2 from high pressure, the latter are connected to the hydraulic tank 10 by opening the flow section of the filling and drain valve 13.

When the pressure in the working cavities of the working hydraulic cylinders 1, 2 is reduced to a certain level due to the fact that the pressure in the working cavities of the return hydraulic cylinders 3, 4 is increased (as a result of their use as a receiver of the working fluid at the first stage of unloading the working cavities of the working hydraulic cylinders 1 , 2 from high pressure) the reverse motion of the movable crosshead 11 automatically starts. At the same time, the flow section of the pressure valve 14 of the return hydraulic cylinders 3, 4 is opened.

To stop the reverse motion of the movable crosshead and stop it, the flow section of the pressure valve 14 of the return hydraulic cylinders 3, 4 is closed.

It should be noted that the proposed method for controlling the movable traverse of the hydraulic press can be implemented without using an additional valve 16 as part of the hydraulic drive of the press. 15 return hydraulic cylinders 3, 4 and, without closing the flow area of the pressure valve 12 working hydraulic cylinders 1, 2, open the flow area of the pressure valve 14 return hydraulic cylinders 1, 2. In this case, as already noted above, they are transferred from the mode of operation under load to the mode of unloading from pressure and their pressure channels are separated from the pressure hydraulic line 7 of the press by check valves that are part of the source of supply of the working fluid 8. In the case of using a pump-accumulator hydraulic drive, the supply of working liquid and into the pressure hydraulic line 7 of the press from the working fluid supply source 8 for this period is stopped by closing the flow area of the two-line on-off shut-off valve with electro-hydraulic control installed in the pressure channel of the working fluid supply source 8 (the rest of the time when the press is operating, the flow area of this valve is open) .

To complete the first stage of unloading the working cavities of the working hydraulic cylinders, the crossheads from high pressure in this case close the flow sections of the pressure valves 12 and 14.

In accordance with the above, when implementing the proposed

of the method for controlling the movable traverse of a hydraulic press, the duration of the working cycle of moving the traverse is reduced by the time required to build pressure in the working cavities of the return hydraulic cylinders and pipelines connected to them before the traverse reverses, thereby increasing the speed of the press (the number of moves of the movable traverse per unit time). The specified pressure increase in the working cavities of the return hydraulic cylinders occurs simultaneously with the first stage of unloading the working cavities of the working hydraulic cylinders of the movable press traverse from high pressure after the end of the working stroke due to a part of the potential energy accumulated during the working stroke of the traverse due to elastic deformations of the fluid and metal structures of the press.

Literary sources

1. Korchak E.S. Dynamic features of the return stroke and the process of unloading the working cylinders from the pressure of forging hydraulic presses. Vestnik mashinostroeniya. 2008. No. 10. pp. 67-70 (p. 68, fig. 2).

2. Goido M.E., Bodrov V.V., Bagautdinov R.M., Alekseev M.A. Reducing pressure fluctuations in the filling and drain pipeline of the forging press hydraulic system // Forging and Stamping Production. Processing of materials by pressure. 2005. No. 4. pp. 30-36 (p. 31, fig. 1).

Claims (1)

A method for controlling a movable traverse of a hydraulic press, according to which, after the completion of the working stroke of the traverse, the supply of working fluid to the working cavities of the working hydraulic cylinders of the traverse is stopped, the working cavities of the return hydraulic cylinders of the traverse are separated from the hydraulic tank, the working cavities of the working hydraulic cylinders of the traverse are unloaded from high pressure in two stages by connecting them at the first stage with the device for receiving the working fluid, and at the second stage by connecting to the hydraulic tank after disconnecting from the device for receiving the working fluid, and the reverse stroke of the traverse is carried out, characterized in that at the first stage the working cavities of the working hydraulic cylinders of the movable traverse are unloaded from high pressure into the working cavities of the return hydraulic cylinders are used as the device for receiving the working fluid, while the working cavities of the working and return hydraulic cylinders are separated after alignment with a given error in the pressure values in these cavities.

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