EP0911129A2 - Mould for making pressed articles - Google Patents

Abstract

The mold has several mold chambers and a vertically movable loading plate connected by hydraulic cylinders to vertically movable pressure plates for the mold chambers. The common pressure source for the hydraulic cylinders (7, 7') is a hydraulic store. A locking valve (28) is fitted in the hydraulic line (25) from the store to the hydraulic cylinders. Each pressure plate (2) may be allocated to at least one hydraulic cylinder.

Description

The invention relates to a mold for the production of Moldings, in particular concrete blocks made of flowable Concrete, with several mold chambers and one vertically movable Load plate that has hydraulic cylinders with vertical movable pressure plates assigned to the mold chambers is connected, the hydraulic cylinder by a common pressure source can be acted upon.

To achieve a uniform compression of the individual mold chambers filled concrete it is known the pressure plates assigned to the mold chambers or their Stamp not rigid, but vertically movable with the To connect the load plate of the molding machine. To do this each pressure plate with a vertically disordered hydraulic cylinder attached to the load plate. Everyone is there Hydraulic cylinder through a common hydraulic line connected with each other. This so-called hydraulic stamp compensation enables during the compression process, where the pressure plates go down through the load plate be pressed, a vertical movement of the hydraulic piston and the associated printing plates relative to each other. The result of this is an even compression in all mold chambers even with uneven filling. Disadvantageous is that due to the vertical relative movements different heights of the printing plates Concrete blocks have to be accepted.

DE 296 03 783 U1 is a multi-chamber shape for mechanical production of molded concrete parts known between the load plate and the individual pressure plates a compressed air chamber is arranged. Are there all compressed air chambers with a common compressed air source connected. So during the compression process vertical movements of the printing plates relative to each other possible in order to achieve a uniform in all mold chambers To achieve compaction. After the compression process the pressure in the compressed air chambers is reduced so much that the pressure plates by spring force into a common upper one Be brought to the stop position. Then the Mold chambers are refilled with concrete and the pressure plates in a second compression stage through the load plates charged again. There is a vertical relative movement between the individual, at the same stop height Printing plates no longer possible, so that in the second compression stage a uniform height of the compacted Concrete is achieved in all mold chambers.

In this known device, the compressed air chamber filled with compressed air after each compression process become. This requires a relatively large amount of energy and is a significant source of noise in addition to the hydraulic system of the molding machine additional energy source (compressed air pump) required. A another disadvantage is that with different Filling level within a molding chamber an even Compaction of the concrete block is only possible to a limited extent and a high compression time would be required, resulting in a Demixing of the concrete leads. Because the pressure plate due to the four rigid guide columns only parallel in can move vertically is an adjustment of the Pressure plate to the different filling level within the Molding chamber not easily possible. This is particularly so important for large concrete blocks.

The invention is based, with relative simple and inexpensive means an even one Compaction and dimensional accuracy of the finished concrete blocks to reach.

According to the invention the object is achieved in that the pressure source is a hydraulic accumulator and in the Hydraulic line from the accumulator to the hydraulic cylinders Shut-off valve is arranged. During the first compression phase is due to the vertical compliance of the Pressure plates against the boost pressure in the memory uniform compaction of the concrete mass in all molding chambers reached while in the second compression phase with the shut-off valve closed due to the intransigence of the pressure plates in all mold chambers, which are made with concrete mass were refilled, an equal amount of finished Concrete blocks is reached.

According to a further feature of the invention, each printing plate assigned at least one hydraulic cylinder.

To achieve vertical movement compensation even within a To obtain the mold chamber is to use two hydraulic cylinders one swivel and one for each pressure plate Rotary-thrust joint between the hydraulic cylinders and the Pressure plate provided. This can, for example with an uneven filling height of the molding chamber Pressure plate by inclining the fill level adjust to ensure even compression of the To achieve concrete mass.

An advantageous construction of the articulation is characterized in that the axes of rotation of the swivel and the rotary push joint transverse to the longitudinal central axis of the Pressure plate run and the thrust axis of the rotary-thrust joint by extending in the direction of the longitudinal central axis Elongated holes of a horizontally movable bearing plate of the Rotary thrust joint is formed.

When using three hydraulic cylinders per pressure plate are each a ball joint and two ball-thrust joints between the pressure plate and the hydraulic cylinders intended. This creates a spatial movement and adjustment the printing plate to an uneven surface of the Allows concrete mass poured into the molding chamber. A advantageous construction of this joint is characterized in that the thrust axis of the first Ball-thrust joint through in the direction of the longitudinal central axis oblong holes of a horizontally movable bearing plate of the first ball-thrust joint is formed while the second ball-thrust joint is designed as a floating bearing which is within the limits of the enlarged through holes a horizontally movable bearing plate of the second ball-thrust joint horizontal in all directions can move.

To avoid an additional energy source, the Storage with the hydraulic system of the molding machine a three-way valve connected.

To adapt to the conditions of the concrete mass, for example different consistency, is that for the first compression stage optimal boost pressure in the store above a preselectable differential pressure switch in the hydraulic line between the accumulator and the hydraulic cylinders is arranged and the three-way valve according to the setpoint automatically into the switch positions switches to increase or decrease pressure.

To the printing plates in their starting position for the second The pistons of the hydraulic cylinders are used to bring the compression stage when lifting the load plate or pressure plates through the boost pressure of the accumulator in their on stop extended end position can be brought and locked.

To between the pistons of the hydraulic cylinder and the Shut-off valve an incompressibility during the second The hydraulic line is to guarantee the compression level between the shut-off valve and the hydraulic cylinders and the supply lines to the hydraulic cylinders and the shut-off valve even integrated into the load plate.

The advantages achieved with the invention are in particular in that the memory of the invention simple way between hydraulic cylinder and Load plate in the hydraulic system of the molding machine integrates. This eliminates a second energy source. The resilience of the printing plates during the first compression phase and its intransigence during the second compression phase is the inventive Storage and control unit in the hydraulic system the molding machine is integrated in the production process controlled so that the memory function an additional hydraulic or compressed air pump. The stepless adjustment of the boost pressure in the The prestressing force of the pressure plates in the memory first compression level to the different circumstances the concrete mass can be adjusted. The high hydraulic Resilience of the memory also allows a relative small dimensioning of the hydraulic cylinders. Furthermore are by using the hydraulic cylinder according to the invention between load plate and pressure plate none separate guides for the pressure plate required because the vertical guidance is taken over by the hydraulic cylinders becomes. The integration of the guides in the hydraulic cylinders also enables the printing plate to be tilted and thus the adjustment to an uneven filling level within the molding chamber, with the result of an even Compaction of the concrete mass also within the Molding chamber.

Fig. 1

einen Querschnitt der erfindungsgemäßen Form,

Fig. 2

eine vergrößerte Schnitt-Darstellung der Druckplattenanordnung nach Fig. 1,

Fig. 3

einen Schnitt durch die Druckplattenbefestigung gemäß der Linie III - III in Fig. 2,

Fig. 4

einen Schnitt durch eine andere Druckplattenbefestigung und

Fig. 5

eine schematische Darstellung der Hydraulikanlage.

The invention is explained in more detail in the following description and the drawing, which represents an embodiment. Show it

Fig. 1

a cross section of the mold according to the invention,

Fig. 2

2 shows an enlarged sectional illustration of the printing plate arrangement according to FIG. 1,

Fig. 3

2 shows a section through the pressure plate fastening along the line III-III in FIG. 2,

Fig. 4

a section through another pressure plate mounting and

Fig. 5

a schematic representation of the hydraulic system.

Fig. 1 shows a vertically movable driven Load plate 1 of a molding machine, not shown for the production of concrete blocks. On the bottom the load plate 1 is a plurality of pressure plates 2 arranged. Each pressure plate 2 is a molding chamber 3 assigned to a form 4 open at the top and bottom. Form 4 is on a mold board 5 of a vibrating table 6 of the molding machine discontinued. Each pressure plate 2 is with the load plate 1 connected via two hydraulic cylinders 7, 7 'to the underside of the load plate 1 are attached. A led down out of the hydraulic cylinder 7 Piston rod 8 of a piston 9 is with the pressure plate 2 connected by a hinge 10, the axis of rotation 11 horizontally and transversely to the longitudinal central axis 12 of the pressure plate 2 runs (Fig. 3). The swivel joint 10 has a bearing plate 13 on that with two dowel screws 14 on the top a reinforcing plate 15 of the pressure plate 2 is screwed on. The reinforcing plate 15 is on the Screwed on top of the pressure plate 2.

The piston rod 8 of the second hydraulic cylinder 7 'is connected to the pressure plate 2 via a rotary-push joint 16, whose horizontal axis of rotation 17 parallel to the axis of rotation 11 of the swivel joint 10 extends. The thrust axis of the Rotary thrust joint 16 runs parallel to the longitudinal central axis 12 of the pressure plate 2 and is through two elongated holes 18 formed, which is in a bearing plate 19 of the rotary push joint 16 are located. Each slot 18 is from a pass collar screw 20 which penetrates into the reinforcing plate 15 of the pressure plate 2 is screwed in so far, that the bearing plate 19 or the entire rotary-push joint 16 in the direction of the longitudinal central axis 12 of the pressure plate 2, delimited by the elongated holes 18, horizontally can move. The swivel joint 10 thus enables together with the rotary push joint 16 also inclined positions of the pressure plate 2nd

4 are between the load plate 1 and the pressure plate 2 three hydraulic cylinders 7 arranged. The piston rods 8 'of the hydraulic cylinders 7 are via a ball joint 21 and two ball-thrust joints 22 connected to the pressure plate 2. The ball joint 21, whose ball pivot with the end of the piston rod 8 'is connected to the bearing plate 13 and two fitting screws 14 on the top of the reinforcing plate 15 a longitudinal axis 12 ′ parallel to the longitudinal central axis 12 screwed one side of the pressure plate 2. The one the two ball-thrust joints 22 is also on the Longitudinal axis 12 'on the other side of the pressure plate 2 the reinforcing plate 15 with the help of the bearing plate 19 and the collar screws 20 screwed so that it is in the boundaries of the slots 18 horizontally in the direction of Longitudinal central axis 12 can move. The second ball-thrust joint 22 is parallel to the longitudinal axis 12 'on the opposite Side with a bearing plate 23 and two Fitting collar screws 20 on the top of the reinforcement plate 15 attached in the form of a floating bearing. Are there the through holes 24 in the bearing plate 23 essential larger than the diameter of the collar screws 20, so be screwed far into the reinforcing plate 15 that the bearing plate 23 with the ball-thrust joint 22 in in all directions, limited by the through holes 24, can move horizontally. With this arrangement of Ball joint 21 and the two ball-thrust joints 22 is a spatial movement of the pressure plate 2 with uneven Filling height of the mold chamber 4 possible.

All hydraulic cylinders 7, 7 'are common Hydraulic line 25 with a hydraulic storage and Control unit 26 and with the hydraulic system 27 of the molding machine connected (Fig. 1). Between the storage and Control unit 26 and the one to the hydraulic cylinders 7, 7 ' leading hydraulic line 25 is a shut-off valve 28 arranged. The hydraulic line 25 and the feed lines the hydraulic cylinders 7, 7 'and the shut-off valve 28 are integrated in the load plate 1.

The storage and control unit 26 consists of a hydraulic accumulator 29 which is connected via the hydraulic line 25 and the shut-off valve 28 with the hydraulic cylinders 7, 7 ' is connected (Fig. 5). Another leads from memory 29 Hydraulic line 30 to a three-way valve 31, the a pressure line 32 with a pump 33 and via a Drain line 34 with a tank 35 of the hydraulic system 27 the molding machine is connected. The three-way valve 31 has three switch positions 36, 37 and 38. The switch position 36 means that the oil circulates without pressure. No oil flows from the pump 33 to the reservoir 29 and there can also be no oil flow from the reservoir 29 into the tank 35. The switch position 36 corresponds to the normal operation of the system in which the oil between the accumulator 29 and the hydraulic cylinders 7, 7 'or the shut-off valve 28 is included.

In Fig. 1 of the drawing, the starting position is the Printing plates 2 shown before the first compression process. The mold chambers 3 are filled with concrete mass. The Shut-off valve 28 of the hydraulic line 25 is open and the three-way valve 31 is in the switching position 36 (Fig. 5). All pistons 9 of the hydraulic cylinders 7, 7 'are due to the boost pressure in the memory 29 down Stop extended. The load plate 1 is lowered and the pressure plates 2 immerse in the mold chambers 3 and press on the filled concrete mass, which by the Vibrating movement of the vibrating table 6 is compressed. Since the Pressure plates 2 in the vertical direction against the boost pressure can yield in the memory 29 is in the mold chambers 3rd the concrete mass is compacted evenly. By using it of two hydraulic cylinders 7, 7 'per pressure plate 2 uniform compression even within a molding chamber 3 reached at an uneven filling level, because the Pressure plate 2 due to the rotary-push joint 16 between Piston rod 8 and pressure plate 2 about the axis of rotation 11 of the Swivel joint 10 or the axis of rotation 17 of the rotary push joint 16 is pivotable and thus assume an inclined position can. 4 is due to the arrangement of the ball joint 21 and the two Ball-thrust joints 22 between the pressure plate 2 and the three hydraulic cylinders 7 also a spatial movement of the Pressure plate 2 possible.

After the first compression process, the load plate 1 with the pressure plates 2 back up to the starting position 1 raised. After that, the Mold chambers 3 filled the remaining concrete mass. The Three-way valve 31 remains in the switch position 36. As a result of the boost pressure in the accumulator 29 are all pistons 9 the hydraulic cylinder 7, 7 'again in its lower stop position. The check valve 28 is now a control line 39 coming from the hydraulic system 27 is closed, so that a vertical movement of the printing plates 2 is no longer possible. The load plate 1 is lowered and the pressure plates 2 press the filled concrete mass while simultaneously shaking Form 5 in all Mold chambers 3 to a uniform height so that the finished concrete blocks are all the same height.

The pressure force of the load plate 1 to compress the Concrete mass is in a known manner via the hydraulic system 27 of the molding machine changeable. This allows the Compressive force the different circumstances, such as e.g. Size of the concrete block, different consistency the concrete mass, volume of the concrete mass, surface size and geometric shape of the concrete block can be adjusted. Accordingly, the pressure in the hydraulic cylinders 7, 7 ', which is between the load plate 1 and the pressure plates 2 are located, adapted to the pressure of the load plate 1 to ensure the optimal movement compensation of the printing plates 2 to ensure during the first compression phase. This is about hiring the appropriate one Boost pressure in memory 29 reached. the adjustment of the Boost pressure in the accumulator 29 takes place with the aid of a differential pressure switch 40 in the hydraulic line 25 is arranged and with which the boost pressure in the accumulator 29 a specific setpoint can be set. In order to is the preload force of the pressure plates for the first one Pre-selectable compression process. The differential pressure switch 40 is via control lines 41 with the three-way valve 31 connected. The switches depending on the setpoint Differential pressure switch 40, the three-way valve 31 automatically in switch positions 37 or 38 (pressure increase or Pressure drop in the accumulator 29). Once the one you want The biasing force is set, the three-way valve 31 automatically returns to switch position 36 (depressurized Oil circulation) reset. In the pressure line 32 is a Pressure relief valve 42 arranged in the switch position 38 (pressure reduction) of the three-way valve 31 the oil from the pump 33 into the tank 35. Possibly emerging Leakage oil during operation is also over the Differential pressure switch 40 by supplying oil from the Hydraulic system 27 balanced.

As a supplement to the differential pressure switch 40 is in the Hydraulic line 25 a manometer 43 is arranged. Since the Preload force of the pressure plates 2 linear depending on the pressure and the pressure plate area and the area of the pistons 9, the preload can be calculated using a conversion table can be read indirectly on the manometer 43.

Claims (10)

Mold for the production of moldings, in particular Concrete blocks made of flowable concrete, with several Mold chambers and a vertically movable load plate, via hydraulic cylinders with vertically movable, connected to the mold chambers associated pressure plates is, the hydraulic cylinder by a common pressure source can be acted upon, thereby characterized in that the pressure source is a hydraulic Memory (29) and in the hydraulic line (25) from the accumulator (29) to the hydraulic cylinders (7, 7 ') a shut-off valve (28) is arranged. Mold according to claim 1, characterized in that each Pressure plate (2) at least one hydraulic cylinder (7) assigned. Mold according to claim 2, characterized in that at two hydraulic cylinders (7, 7 ') per pressure plate (2) each have a swivel joint (10) and a rotary push joint (16) between the hydraulic cylinders (7, 7 ') and the Pressure plate (2) is provided. Mold according to claim 3, characterized in that the Axis of rotation (11) of the swivel joint (10) and the axis of rotation (17) of the rotary-thrust joint (16) transverse to the longitudinal central axis (12) of the pressure plate (2) and the Thrust axis of the rotary-thrust joint (16) in the direction the longitudinal central axis (12) of the pressure plate (2) running elongated holes (18) of a horizontally movable Bearing plate (13) of the rotary push joint (16) is formed. Mold according to claim 2, characterized in that at three hydraulic cylinders (7) per pressure plate (2) each a ball joint (21) and two ball-thrust joints (22) between the pressure plate (2) and the hydraulic cylinders (7) are provided. Mold according to claim 5, characterized in that the Thrust axis of the first ball-thrust joint (22) through in the direction of the longitudinal central axis (12) of the pressure plate (2) extending elongated holes (18) one horizontally movable bearing plate (19) is formed while the second ball-thrust joint (22) is designed as a floating bearing is that is within the limits of the enlarged Through holes (24) of a horizontally movable Bearing plate (23) of the second ball-thrust joint (22) can move horizontally in all directions. Mold according to one of claims 1 to 6, characterized in that that the memory (29) with the hydraulic system (27) of the molding machine via a three-way valve (31) connected is. Mold according to claim 7, characterized in that the Boost pressure in the memory (29) via an adjustable Differential pressure switch (40) can be preselected in the Hydraulic line (25) is arranged and the three-way valve (31) according to the setpoint automatically to switch positions (37) or (38) Pressure increase or decrease switches. Mold according to one of claims 1 to 8, characterized in that that the pistons (9) of the hydraulic cylinders (7, 7 ') when lifting the load plate (1) or the pressure plates (2) by the pressure in the memory (29) in their Extended position can be brought to the stop and are lockable. Mold according to one of claims 1 to 9, characterized in that that the hydraulic line (25) and its feed lines to the hydraulic cylinders (7, 7 ') and that Shut-off valve (28) integrated in the load plate (1) are.

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