RU2461462C2 - Hydraulic press - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to metal forming, particularly, to hydraulic presses. Proposed press comprises stationary and moving crossbars, two drive and two return cylinders, pump station and moving crossbar control system. System comprises two double booster dispenser and double reducer dispenser. Each of said devices incorporates inlet cylinder and two dispensing cylinders with plungers that make moving unit. Plunger units are rigidly interconnected. Press uses hydraulic valve system including four-way three-position reverse slide valve, two shutoff two-position slide valves, two pressure relays, six check valves, and extra four-way two-position reverse slide valve. Chamber of aforesaid dispensing cylinders are arranged along booster dispenser periphery and communicated via check valves with one of drive cylinders.

EFFECT: higher efficiency.

3 cl, 1 dwg

Description

The invention relates to the processing of metals by pressure, and in particular to the design of hydraulic presses.

A hydraulic press is known, comprising a movable traverse connected to a lagging and leading hydraulic cylinders, a table, a main multiplier, an additional multiplier, the input of which is connected to the main multiplier, as well as a traverse skew compensation device and an associated three-position spool valve connecting the output of the additional multiplier to the lagging a hydraulic cylinder, while in the pipeline connecting the additional multiplier with a three-position spool distribution castor, installed a two-position spool valve (AS USSR No. 829453, class B30V 15/24, 1981).

The disadvantage of this press is a decrease in efficiency due to the increased installation capacity of the pumps, which is associated with the use of a multiplier-dispenser for idling the press.

The closest in technical essence and the achieved result is a hydraulic press containing a fixed and movable beam, two power and two return cylinders, pairwise connected with the ends of the said beam, a pump station, a system for controlling the movement of a movable beam, including a double multiplier-dispenser and a double gearbox a dispenser, each of which is made with an inlet and two metering cylinders with plungers forming a movable block of plungers, while the cavities of the metering cylinders are double mule the dosing-metering device and the double-metering gearbox are connected to one of the power cylinders; a hydraulic system, including a four-way three-position reversing valve, connecting the pumping station with return cylinders and through a common three-way two-position valve, with cavities of the input cylinders of the multiplier-dispenser and the gearbox-metering; two shut-off two-way on / off slide valves installed, respectively, on the pipeline of the input cylinder of the metering gearbox and on the pipe connecting the cavities of the power cylinders with the pipeline of the input cylinder of the metering gearbox; two pressure switches installed, respectively, on the common pipeline of the return cylinders and on the pipeline of the input cylinder of the metering gearbox (RU 2084348 C1, V30V 15/24, 07.20.1997).

The disadvantage of this press is the large hydraulic losses in the pipelines when the movable block of plunger of the multiplier-dispenser is returned to the initial position (charging operation of the multiplier-dispenser) by filling the cavities of its dispensing cylinders with liquid displaced from the power cylinders during the reverse stroke of the press. This requires an increase in the size of the return cylinders or the installation of high pressure pumps, the power of which will not be fully used in other operations. An increase in the size of the return cylinders leads to an increase in the duration of the working cycle and a decrease in productivity; the installation of high pressure pumps leads to a decrease in efficiency.

The objective of the claimed device is to increase the efficiency of the press and its performance by reducing hydraulic losses when charging the multiplier-dispenser.

The problem is achieved in that a hydraulic press containing a fixed and movable crosshead, two power and two return cylinders, pairwise connected with the ends of the said traverse, a pumping station, a control system for the movement of the movable crosshead, including a double multiplier-dispenser and a double reduction gear-dispenser, each of which is made with an inlet and two metering cylinders with plungers forming a movable block of plungers, while the cavities of the metering cylinders of the double multiplier-dispenser and double uktora-dispenser connected with one of the cylinders; a hydraulic system, including a four-way three-position reversing valve, connecting the pumping station with return cylinders and through a common three-way two-position valve, with cavities of the input cylinders of the multiplier-dispenser and the gearbox-metering; two shut-off on-off spools installed, respectively, on the pipeline of the input cylinder of the metering gearbox and on the pipeline connecting the cavities of the power cylinders with the pipeline of the input cylinder of the metering gearbox; according to the invention, equipped with six check valves, an additional four-way two-position reversing valve and coaxially mounted with a main additional double metering multiplier with an input and two metering cylinders with plungers forming a movable block of plungers, which is rigidly connected with the block of plungers of the main multiplier-dispenser and supply with a rod interacting with a switching device for an additional four-way two-position reversing valve, and the cavities of the metering cylinders of each metering multiplier, having a peripheral location in the assembly of metering multipliers, are separately connected via one-way valves to one of the power cylinders, and one of the outputs of the additional four-way two-position reversible spool connected to the cavity of the input cylinder of the main multiplier-dispenser and through a check valve - cavities metering cylinders of the metering additional multiplier, and a second output further four-way two-position reversing valve connected with the cavity inlet cylinder further multiplier-dispenser and through the check valve with the cavities of the metering cylinder main metering multiplier; one of the inputs of the additional four-way two-position reversible spool is connected to the drain, and the second input of this spool is connected to one of the outputs of the common three-way two-position spool.

To increase the reliability of the press, a three-way on-off slide valve is installed on the common pipeline of the return cylinders, one of the outputs of which is connected directly to each return cylinder, the second output is connected to the inlet of the flow divider, the outputs of which are separately connected to one of the return cylinders.

Additionally, to increase the reliability of the press, it is equipped with two adjustable stops for fixing the upper initial position of the movable beam.

Inclusion of six check valves into the press system, an additional four-way two-position reversing valve and coaxially installed with the main additional double metering multiplier with an input and two metering cylinders with plungers forming a movable plunger block, which is rigidly connected to the plunger block of the main metering multiplier and is equipped with a bar interacting with a switching device for an additional four-way two-position reversible spool; connecting the cavities of the metering cylinders of each multiplier-dispenser having a peripheral location in the assembly of the multiplier-dispensers, separately, through check valves with one of the power cylinders; the connection of one of the outputs of the additional four-way two-position reversing valve with the cavity of the input cylinder of the main multiplier-dispenser and through the check valve with the cavities of the metering cylinders of the additional multiplier-dispenser; the connection of the second output of the additional four-way two-position reversing valve with the cavity of the input cylinder of the additional multiplier-dispenser and through a check valve with the cavities of the metering cylinders of the main multiplier-dispenser; the connection of one of the inputs of an additional four-way two-position reversible valve with a drain, and the second entrance of this valve with one of the outputs of a common three-way two-position valve, together with other essential features, exclude the charging operation of the multiplier-dispenser and the associated large hydraulic losses in pipelines and, as a result, they increase the efficiency and productivity of the press.

Installation on a common pipeline of return cylinders of a three-way two-position valve with the connection of one of its outputs directly to each return cylinder, the second output - with the input of the flow divider, the outputs of which are separately connected to one of the return cylinders, provides synchronous movement of the movable crosshead during the press return and free draining fluid from return cylinders during working and idling. This increases the reliability of the press.

The installation of two adjustable stops for fixing the upper initial position of the movable beam eliminates possible slight distortions of the movable beam after each cycle of the press. This also improves the reliability of its work.

The hydraulic press is illustrated in the drawing, which shows a diagram of the press.

The hydraulic press contains a fixed crosshead 1, a movable crosshead 2, two power cylinders 3, two return cylinders 4, two adjustable stops 5, a pump station 6, a double metering gear 7 with an inlet plunger cylinder 8 and with two metering plunger cylinders 9;

two double metering multipliers 10 and 11 with inlet plunger cylinders 12 and 13 and with metering plunger cylinders 14 and 15, respectively. The plungers of the cylinders of each multiplier-dispenser with diameters D _m and d _m form movable blocks 16 and 17, which are connected by rods 18 into a common movable block. The cylinder plungers of the metering gearbox with diameters D _p and d _p form a movable block 19. A four-way three-position reversible spool 20 with electromagnets 21 and 22 is connected to the pressure line of the pump station with its second input connected to the drain. One of the outputs of this spool by a common pipe 23 is connected to the input of a three-way on-off spool 24 with an electromagnet 25, the open output of which is connected directly to each return cylinder, and the closed output is connected to the input of the flow divider 26, the outputs of which are separately connected to one of the return cylinders. A pressure switch 27 is connected to the pipe 23. The second output of the reversible spool 20 is connected to the input of a three-way on-off valve 28 with an electromagnet 29, the open output of which is through a pipe 30, through a shut-off two-way on-off valve 31 with an electromagnet 32, connected to the input cylinder 8 of the metering gear and to a pressure switch 33 is connected to this pipeline. The metering cylinders 9 of the metering gearbox are separately connected to one of the power cylinders 3 and through the shut-off valve 34 with an electromagnet 35 to the pipeline 30. The second closed outlet of the spool 28 is connected to one of the inputs of the four-way two-position reversible spool 36 with a switching device 37, the second input of which is connected to the drain. With the device for switching 37 interacts rod 38, mounted on a common movable block of multipliers-dispensers. The cavities of the metering cylinders 14 of the multiplier-dispenser 10 are separately connected through check valves 39 and 40, respectively, to one of the power cylinders and together, through a check valve 41, to the input cylinder 13 of the multiplier-dispenser 10 and to one of the spool outputs 36. Cavities the metering cylinders 15 of the multiplier-dispenser 11 separately, through check valves 42 and 43, respectively, are connected to one of the power cylinders and together, through the check valve 44, with the input cylinder 12 of the multiplier-dispenser 10 and with the second output a 36.

The hydraulic press operates as follows. The working cycle of the press occurs when the station pumps are running and includes periods of idle, working, and reverse, with the movable crosshead and the block of gearbox plungers being brought to their initial position.

Idling of the press starts from the position in which the movable crosshead 2 occupies the highest position, the movable block of the plunger of the gearbox-dispenser - the lower position and the movable block of the plunger of the multiplier-dispenser - an arbitrary position (according to the scheme). For its implementation, the electromagnet 21 is turned on. The reversible spool 20 occupies a position in which the input cylinder 8 of the metering gearbox is connected via the spools 28, 31 in the initial positions to the pressure line of the pumping station, and the return cylinders through the spool 24 located in the initial position are connected to the drain . In this case, the liquid from the pumping station enters the inlet cylinder of the metering gearbox and moves its movable block 19 upwards (according to the diagram), which displaces the liquid from the metering cylinders 9 into the power cylinders, which ensures their synchronous movement together with the movable crosshead 2 downward (according to the diagram ) From the return cylinders, the liquid through the spool 24 through the pipe 23 is displaced to the drain.

The increase in pressure in the power cylinders, which controls the pressure switch 33, corresponds to the beginning of the working stroke. In this case, the electromagnet 29 is turned on and the spool 28 occupies a position at which the pipeline 30 closes, and the liquid from the pumping station enters the inlet of the reversible spool 36. Depending on which position (of the two) this spool takes, the liquid will then flow in two directions. When the spool is in the main position (circuit), the liquid simultaneously enters the inlet cylinder 12 of the multiplier-dispenser 10 and in the metering cylinders 15 of the multiplier-dispenser 11. In this case, the common movable block of plunger of multiplier-dispenser moves upward (according to the diagram), displacing the high-pressure liquid from the metering cylinders 14 through the check valves 39, 40 to the power cylinders, ensuring their synchronous movement down (according to the scheme) with the displacement of liquid from the return cylinders to drain. The liquid from the inlet cavity 13 of the multiplier-dispenser 10 through the spool 36 is displaced to the drain. At the end of the stroke of the common block of plunger of dispensing multiplier plungers (according to the diagram), the rod 38 connected to this block contacts the device 37 and puts the spool 36 into the second position, at which the liquid from the pumps enters simultaneously into the inlet cylinder 13 of the multiplier-dispenser 11 and through the check valve 41 to the metering cylinders 13 of the multiplier-dispenser 10. In this case, the common block of plunger multipliers moves downward (according to the diagram), displacing the high-pressure liquid from the metering cylinders 15 of the multiplier-dispenser 11 through the sample tnye valves 42 and 43 in the power cylinder, while continuing their downward movement synchronous (scheme) with the fluid displacement of the return cylinders on the drain. The liquid from the inlet cylinder 12 of the multiplier-dispenser 10 is forced to drain through the spool 36. At the end of the stroke of the common block of plunger of multiplier-dispenser down (according to the diagram), the rod 38 comes into contact with the device 37 and puts the spool 36 to its original position. A new cycle of dispenser multipliers begins. And so, until the complete completion of the working stroke.

The reverse stroke of the press occurs when the electromagnet 22 is turned on. At the same time, the reversible spool 20 occupies the position at which the pressure line of the pumping station is connected to the pipeline 23 and then, through the spool 24 located in the initial position, to the return cylinders 4. The drain line of the pumping station by the pipeline 30 through the spools 28 and 31 located in the initial positions, it is connected to the input cylinder 8 of the metering gear 7. As a result, the liquid from the pumping station enters the return cylinders that move the movable Raversi up (scheme). From the power cylinders, the liquid is displaced into the metering cylinders 9 of the metering gearbox and moves its movable block of plungers 19 to its original position (down, according to the diagram). The fluid from the inlet cylinder 8 of the metering gearbox goes to drain through the spools 20, 28 and 31. The flow of fluid from the power cylinders to the metering cylinders of the metering gearbox provides synchronous bevel-free movement of the movable crosshead. After the block of the gearbox plungers returns to their original position, the fluid left in the power cylinders is supplied to them during the working stroke. To drain this fluid, an additional electromagnet 35 of the spool 34 and an electromagnet 25 of the spool 24 are turned on. The spool 34 opens the drain of the liquid from the power cylinders through the pipe 30 and through the spools 28 and 20. In this case, the fluid enters the return cylinders through the flow divider 26, which ensures an off-balance the movement of the movable yoke. When the movable beam crosses into contact with one of the stops 5, the electromagnet 25 is turned off and the spool 24 takes its initial position. The fluid coming from the pump station to the return cylinders directly, bypassing the flow divider, provides the contact of the movable beam with two stops. This eliminates the possible slight distortion of the traverse, which she can get during one working cycle. A further increasing pressure in the return cylinders, which controls the pressure switch 27, corresponds to the end of the press working cycle and the beginning of a new one.

The necessary signals to enable (disable) the solenoid solenoids, in addition to the pressure switches used, can be obtained from the limit switches that control the position of the moving elements of the press and the metering gear (not shown in the diagram).

Installation of an additional dispenser-multiplier, blocking it with the main dispenser-multiplier and with an additional four-way on / off slide valve provides a continuous supply of high-pressure fluid to the power cylinders during the working stroke of the press. This eliminates the charging operation of the multiplier-dispenser and the associated large hydraulic losses in the pipelines and, as a result, provides increased efficiency and productivity of the press.

Claims (3)

1. A hydraulic press comprising a fixed crosshead, a movable crosshead, two power cylinders and two return cylinders in pairs connected to the ends of the said crosshead, a pump station, a control system for moving the movable crosshead, including a double multiplier-dispenser and a double reducer-dispenser, each of which is made with an inlet and two metering cylinders with plungers forming a movable block of plungers, while the cavities of the metering cylinders of the double multiplier-dispenser and the double reducer-dispenser are connected to one them from power cylinders, a hydraulic system, including a four-way three-position reversible spool, connecting the pumping station with return cylinders and through a common three-way two-position spool - with cavities of the input cylinders of the multiplier-dispenser and the metering reducer, two shut-off two-position spools installed respectively on the pipeline of the input cylinder the metering gearbox and on the pipeline connecting the cavities of the power cylinders with the piping of the input cylinder of the metering gearbox, dv a pressure switch installed respectively on the common pipeline of the return cylinders and on the pipeline of the input cylinder of the metering gear, characterized in that it is equipped with a system of six check valves, an additional four-way two-position reversible spool and coaxially mounted with the main additional double metering multiplier with an input and two metering cylinders with plungers forming a movable block of plungers, which is rigidly connected to the block of plungers of the main multiplier-dispenser and equipped with a bar interacting with a switching device for an additional four-way two-position reversing valve, and the cavities of the metering cylinders of each metering dispenser have a peripheral location in the metering device and are separately connected via one-way valves to one of the power cylinders, while one of the outputs of the additional four-way two-position reversing valve connected to the cavity of the input cylinder of the main multiplier-dispenser and through a check valve - with cavities of the metering cylinders of the additional multiplier-dispenser, and the second output of the additional four-way two-position reversing spool is connected to the cavity of the inlet cylinder of the additional multiplier-dispenser and through the check valve to the cavities of the metering cylinders of the main multiplier-dispenser, one of the inputs of the additional four-way two-position reversing spool is connected to the drain , and the second entrance - with one of the outputs of a common three-way on / off valve. 2. The press according to claim 1, characterized in that a three-way on-off slide valve is installed on the common return pipe cylinder, one of the outputs of which is connected directly to each return cylinder, the second output - with the input of the flow divider, the outputs of which are separately connected to one of the return cylinders . 3. The press according to claim 1, characterized in that it is equipped with two adjustable stops for fixing the upper initial position of the movable beam.

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