DE20216874U1 - Ceramic industry press, for manufacturing roof tiles, has knee lever linked to plunger powered by linear drive with variable pressure application - Google Patents

Abstract

A ceramic industry press has a plunger (6) operating in conjunction with a press bench (4), supported by a stand (1). The plunger is powered through a linear drive (5). A knee lever (2) is located between the linear drive (5) and the plunger (6). During the press cycle the plunger press force is regulated.

Description

HA01 EO25DEU/tsO2s12/TW-Dr. Mm/ts/30.10.2002 Handle GmbH, Industriestraße 47, 75417 Mühlacker

Press for the ceramic industry

Description:

The invention relates to a press for the ceramic industry with the features specified in the preamble of claim 1. Such presses are known and commercially available.

During a press cycle, the pressing force exerted by the ram on a pressing material changes with increasing stroke. The pressing force exerted by the ram at a certain point in time or at a certain stroke is described by a pressing curve that depends on the drive and geometry of the press. In the ceramics industry, there is a need to adapt the pressing curve of a press to the flow behavior of the clay to be processed in order to achieve optimal processing for high-quality products.

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With eccentric presses, the pressing curve of a press can be changed by replacing the eccentric disc and thus adapted to changing requirements. The disadvantage of this is that the relatively high weight of a typical eccentric disc makes replacement laborious and time-consuming. In addition, the pressing curve can only be adjusted in a very small range in this way.

In the case of presses that are driven by an electric motor that drives a spindle, the pressing curve can in principle be changed if it is a servo motor, but a suitable electric motor would require an unacceptably high level of power due to the high pressure forces required, for example, in a roof tile press.

The object of the invention is therefore to provide a press for the ceramic industry which allows the pressing curve to be adapted to changing production requirements without great effort.

This object is achieved by a press having the features specified in claim 1. Advantageous developments of the invention are the subject of the subclaims.

According to the invention, the drive moves the ram via a toggle lever arrangement by means of a linear force transmitter and means are provided with which the pressure exerted by the ram on the pressing material can be controlled during a pressing cycle.

The characteristic curve of a toggle lever press is characterized by the fact that the pressing force exerted by the ram is initially low at the beginning of a pressing cycle, increases progressively with the stroke and only increases sharply in the last section of the ram stroke when approaching the bottom dead center (extended position of the toggle lever arrangement). Such a characteristic curve is advantageous when stamping metal, but undesirable when pressing clay lumps, since

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Due to the plasticity of clay, a high pressing force is not only required for the last part of the ram stroke, i.e. shortly before the bottom dead center is reached, but over a larger area, which begins when the mold is closed and depends on the height of the lump. For this reason, toggle lever presses have so far been unusual for the ceramics industry. The merit of the present invention is that it shows that by combining a toggle lever with a linear force transmitter instead of the crank or eccentric drive usual in toggle lever presses, a press can be created which is excellently suited to the ceramics industry. A linear force transmitter, preferably a hydraulic cylinder, can easily be provided with means to at least briefly increase the force exerted on the toggle lever and thus also the pressure exerted by the ram on the pressing material.

In this way, the pressing curve of a toggle press can be shifted to a higher pressing force from a freely selectable ram position by using the means mentioned, which preferably contain one or more hydraulic accumulators. Another possibility of being able to influence the pressing curve is also provided by servo valves provided in the hydraulic circuit.

In a press according to the invention, the ram initially moves very quickly with only a low pressing force due to the geometry of the toggle lever, which is welcome for the rapid closing of the press mold and allows for high cycle times. When the upper mold then hits the lump to be formed, the pressing force can be increased, in particular by switching on a hydraulic accumulator, so that, for example, an increased pressing force is available for the second half of the ram stroke. It does not matter if the pressure increased by switching on the hydraulic accumulator in the hydraulic cylinder is only available for a short time and soon drops again. Due to the rapid increase in the characteristic curve of a toggle lever arrangement when approaching its bottom dead center, the pressure with the

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The pressure drop that occurs when the hydraulic accumulator is emptied and the piston in the hydraulic cylinder continues to move is quickly overcompensated, so that after the molds are closed, i.e. when the upper mold hits the lump and the hydraulic accumulator is then switched on, there is a progressive increase in the pressing force.

Since the capacity and number of hydraulic accumulators as well as the time(s) of their activation can be freely selected within wide limits, the pressing curve initially specified by the characteristic curve of the toggle mechanism can be easily modified and optimally adapted to the requirements of the flow behavior of different clays and the requirements of a wide variety of ceramic products. This is particularly true if - as is preferred - several hydraulic accumulators are provided which can be activated independently of one another. By selecting the number of hydraulic accumulators, by dimensioning their load and by selecting the time of their activation, not only the course of the pressing force over the stroke can be changed, but also the speed of the pressing process, so that productivity can also be maximized. The pressure course over the stroke and the temporal course of the stroke can also be advantageously changed and the operation of the press optimized by assigning a servo valve to each hydraulic accumulator, with which the pressure drop can be controlled after the hydraulic accumulator is activated.

The present invention thus allows a working method in a press for the ceramics industry, which has a stand, a press table, a ram working against the press table, a drive in connection with a linear force transmitter and a toggle lever arrangement, which is provided between the linear force transmitter and the ram, in which the drive is controlled in such a way that a force or pressure ramp is superimposed on the predetermined characteristic curve of the toggle lever arrangement at a selectable time, so that compared to the characteristic curve of a press subjected to constant force

The knee lever arrangement results in an early pressure increase at the preselected time. The pressure ramp can be limited to a short period of time and then decrease again. The decrease is overcompensated by the steeper increase in the characteristic curve of the knee lever arrangement. The pressing force can advantageously be limited to a maximum value that is based on what the press can withstand without being damaged. This working method can be advantageously further developed by controlling or regulating the steepness of the ramp. This and the choice of the height of the ramp also allow the working speed of the press and the temporal progression of the press stroke to be optimized.

The press is preferably driven by a hydraulic unit. This is a proven way of applying the pressing forces required for the ceramics industry. The hydraulic accumulator is preferably designed as a bladder accumulator. Bladder accumulators are advantageously characterized by a short response time and low hysteresis. Weight accumulators, spring accumulators and hydropneumatic accumulators without a partition are also suitable.

Further details and advantages are explained using an embodiment with reference to the accompanying drawings.

Show it:

Figure 1 shows an embodiment of a press according to the invention in

¹ cross section,

Figure 2 shows a hydraulic plan for supplying the press and

Figure 3 shows an exemplary pressing curve.

The embodiment shown in Figure 1 is an anvil press for roof tiles. The press has a stand 1 which carries a press table 4 with lower molds 7a, which are supplemented by upper molds 7b to form molds 7, which are shown closed in the left half of the picture A and open in the right half of the picture B. The molds 7 are closed by operating the ram 6, also referred to as the pressure piece, on the underside of which the upper molds 7b are located. Pressing material, e.g. clay, introduced into the lower molds 7a is pressed into its desired shape, here that of a roof tile, by closing the molds 7. The ram 6 is moved by a hydraulic cylinder 5 via an arrangement of two toggle joints 2. The left half of Figure 1 shows the toggle joint 2 in its extended position, in which the ram 6 is moved over its full stroke to the bottom dead center. The right half of Figure 1, marked B, shows the press in its open position, in which the ram 6 is in its top dead center position and the toggle joint 2 is bent. Each mold 7 is additionally assigned a hydraulic cylinder 3 which acts on the upper molds 7b and with which the molds 7 are preloaded.

The hydraulic plan shown in Figure 2 shows the hydraulic system associated with the hydraulic cylinder 5. A hydraulic unit 10 with two hydraulic pumps 1OA and 1OB serves to generate the hydraulic pressure required in the hydraulic system to actuate the hydraulic cylinder 5. For the sake of a better overview, functionally related areas are grouped together in the hydraulic plan shown in Figure 2 by boxes, which are provided with reference numbers and are described in more detail below.

The hydraulic unit 10 has a pump 10A with power pressure control and a high-pressure pump 10B, driven by an electric motor 10C, and thus generates the hydraulic pressure required to actuate the tappet 5. The hydraulic unit 10 and its pumps 10A and 10B also serve to control two hydraulic accumulators 11, 12 designed as bladder accumulators with the same

or different pressure levels. The two bladder accumulators 11 and 12 can be switched on at a selectable time during the pressing cycle and thus quickly increase the pressing force.

Adjustable throttle valves, in particular servo valves 15 and 16, offer another way of influencing the press curve. They can be used to control how quickly the bladder accumulators 11 and 12 empty after they have been switched on and how steep the increase in the press force is that they trigger. The servo valves 15 and 16 can also be used to influence the speed of the press stroke and its progression over time.

The purpose of a safety block 13 is to prevent uncontrolled sagging of the ram 5 in the event of a defect. A cooling unit 14 serves to prevent dangerous overheating of the hydraulic fluid.

Figure 3 shows an example of a press curve for the embodiment of a press described with reference to Figures 1 and 2. In Figure 3, curve a describes the course of the pressure ρ prevailing in the hydraulic system as a function of the stroke of the hydraulic cylinder 5. The pressure ρ generated in the hydraulic system by the hydraulic unit 10 and its pump 10A is 100 bar in this example. This pressure prevails in the hydraulic system up to a stroke of the hydraulic cylinder 5 of approximately 150 mm. When the hydraulic cylinder 5 reaches this position, the bladder accumulator 11 is switched on, which leads to a rapid increase in the pressure ρ in the hydraulic system to over 300 bar. Due to unavoidable pressure losses and the movement of the hydraulic cylinder 5, the pressure then drops back to its original value of 100 bar over time as the hydraulic cylinder 5 continues to move. With the pressure according to curve a, the hydraulic cylinder 5 acts on the toggle lever arrangement 2, which converts the hydraulic pressure ρ into a pressing force. Curve b in Figure 3 shows schematically the characteristic curve of the toggle lever arrangement 2, i.e. the dependence of the pressing force exerted by the ram 6, as it occurs with a

constant pressure ρ of, for example, 100 bar in the hydraulic system due to the geometric conditions of the toggle lever 2 shown in Figure 1. The pressing force exerted by the ram 6 on the pressing material in the mold 7 is indicated in tons by the right of the two vertical axes labeled "pressing force".

Finally, curve c shows the course of the pressing force exerted by the ram 6, as it can result when the bladder accumulator 11 is switched on from a cylinder stroke of approximately 150 mm. By switching on one or both bladder accumulators 11, 12, the pressing curve b, which depends on the geometry and characteristic curve of the toggle lever 2, can be changed to the pressing curve c in accordance with the flow behavior of a clay to be processed. In particular, it can be achieved that when the pressing molds 7 are closed, which happens, for example, when the hydraulic cylinder 5 has a stroke of approximately 150 mm, a considerably higher pressing force is exerted, which is initially not achievable with a toggle lever press. After the pressing mold 7 is closed, the pressing force increases progressively due to the characteristic curve of the toggle lever 2, which overcompensates for the pressure drop in the hydraulic system that is inevitable after the bladder accumulator 11 is switched on, so that despite the pressure drop in the hydraulic system, the pressing force continues to increase, which is extremely advantageous. In this way, a pressing curve can be set that is suitable for the respective product requirements and clays.

Claims (7)

1. Press for the ceramics industry with a ram ( 6 ) which interacts with a press table ( 4 ), and a stand ( 1 ) which carries the ram ( 6 ) and the press table ( 4 ), with a drive and a linear force transmitter ( 5 ) for moving the ram ( 6 ), characterized in that a toggle lever arrangement ( 2 ) is provided between the linear force transmitter ( 5 ) and the ram ( 6 ) and that means ( 11 , 12 ) are also provided with which the pressure exerted by the ram ( 6 ) on the pressing material can be controlled during a pressing cycle. 2. Press according to claim 1, characterized in that means ( 15 , 16 ) are provided to control the temporal course of the stroke of the press. 3. Press according to claim 1 or 2, characterized in that the drive is a hydraulic unit ( 10 ). 4. Press according to one of the preceding claims, characterized in that the linear force transducer ( 5 ) is a hydraulic cylinder. 5. Press according to one of the preceding claims, characterized in that the means for controlling the pressure exerted by the ram ( 6 ) on the pressing material during a pressing cycle include one or more hydraulic accumulators ( 11 , 12 ) which can be connected to the drive or the linear force transmitter ( 5 ) during the pressing cycle. 6. Press according to claim 5, characterized in that the hydraulic accumulator ( 11 , 12 ) is a bladder accumulator. 7. Press according to claim 4 or 5, characterized in that a controllable throttle valve, in particular a servo valve ( 15 , 16 ), is associated with the hydraulic accumulator or accumulators ( 11 , 12 ).