DE249025C - - Google Patents

Description

IMPERIAL

PATENT OFFICE

CLASS 106th GROUP

in Berlin.

It is known that for the production of briquettes and for compressing smaller Bodies which are to be united into a whole, a complete venting of the Material is a prerequisite in many cases, especially when one of special Wants to refrain from binding agents. The venting process can be viewed in different ways Think wise coming into being.

The most obvious thing seems to be the application of a momentary very high, sudden pressure; however, "venting" to the desired extent occurs here not because, on the one hand, the air at

^J 5 ianer shock effect is no time to escape, while on the other hand, an extraordinary use of the machine and inefficient utilization of the same would be connected thereto. The same disadvantages occur if the pressure effect does not take place intermittently, but very quickly, and if the maximum pressure reached is then held for a certain time.

Another way to vent is to keep the pressure continuously up to a To increase the maximum limit, whereby, expediently using sliding molds, the air pushed to the sides is given the opportunity to escape.

With such a pressing method there is a layer-by-layer ventilation, which gradually propagates further from the movable ram to the fixed counter ram.

It was now. found that a continuous increase in pressure, i.e. H. such, at which in the unit of time or in any equal fraction that for the pressing process provided time an exactly the same increase in pressure is always produced that Briquetting or pressing processes do not yet make a completely rational one can. This observation was made from the knowledge that the amount of pressure increase in the unit of time or in each fraction of the time allotted for the pressing process is related to the air content that is present in the relevant stage of the pressing process. The greater the air content, the slower the pressure increase must be in the unit of time bz \ v. in any fraction of the total time available while with decreasing air content, the greater the pressure increase "within the unit of time may take place.

Material properties - like the specific one The density and the porosity of the heaped mass are in the same way as the air content close technical connection that for the pressure curve, which according to the air content for the pressing process is to be constructed,

the specific density and porosity of the material can serve as a basis.

On this knowledge of the dependence on the increase in pressure at every moment the pressing process depends on the air content of the material at that moment and it is in the application of this knowledge to practice that the essence of the invention resides. The same can not only be used for substances that were previously briquetting were subjected, such as coal, salt, sawdust, ores, but also to production of solid bodies of granular, dusty, leafy, fibrous or other masses composed of small individual parts, from paper disks, metal sheets 'u. the like, for example for the purpose of alloying metals on the pressing surfaces cold way by producing the so-called "cold liquid state" and the like.

The method according to the invention is carried out in such a way that under an and for himself 'better known. Applying several pressure levels the pressure level and the pressure duration of each stage is adapted to the respective air content of the pressed material in such a way that with decreasing air content either the pressure increase increases in the same times or the time for the same pressure increases decreases.

The most economical pressing method for each material will be found on most expedient in an empirical way, for example in such a way that one controls the control organs regulates or adjusts during successive pressing processes until complete usable briquettes ventilated in all layers are obtained; is this State reached, it can be concluded from this that for the material in question the most economical pressing method is obtained.

In the accompanying drawing "is illustrated by a diagram (Fig. 1) how such an approximation of the actual pressing process to the most economical pressing method is aimed for or achieved. The horizontal coordinate indicates the times taken for the pressing in seconds, while on the vertical coordinate the pressures in atmospheres, corresponding to these times and a certain material, are shown. The ideal pressure curve is illustrated by i . A pressure level of 2000 atm. and a duration of 16 seconds are assumed. It can be seen that At Vt the time available for the pressing process, namely after 4 seconds, a pressure of about 120 kg is applied first, after 8 seconds on the other hand about 360 kg, after 12 seconds a pressure of about 875 kg, after 14 seconds a pressure of about 1300 kg, after 15 seconds a pressure of about 1575 kg, etc.

If the total pressure level is divided into a number of pressure levels, for example ⁶ S in eight, as can be seen from Fig. 1 of the accompanying drawing, it can be seen that the duration of the pressure levels becomes shorter and shorter with increasing pressure level, corresponding to the course of the ideal pressure curve i; the first pressure stage I lasts for 6 seconds, the second pressure stage for about 3 seconds, the third for about 2 seconds, and so on, while the last pressure stage _{lasts for about V 2} seconds.

It can be seen from the diagram that the fewer the number of pressure levels, the smaller the number less an adaptation of the pressing process to the ideal pressure stage takes place while on the other hand, with an increasing number of pressure levels, the compression process equates to the ideal relationships. Of further results from the diagram that with increasing increase in the number of Pressure levels The vibrations that occur when transitioning from one pressure level to the other occupy an ever larger fraction of the total period of time, whereby a favorable, almost permanent one for the ventilation Shaking movement · is caused.

While the ideal pressure curve i indicates those pressures which are exerted on the material by the effective surface of the working ram, i.e. by the briquette pressing surface, / means the ideal curve of those pressures exerted by the pressurized water on the hydraulic piston; here a four-fold translation between the hydraulic piston surface and between the briquette press ram is assumed, so that a pressure of 2000 atm. the latter a pressure of 500 atm. corresponds to the former, that is, at any given moment in the process, the ordinate of a point on the curve / is the fourth part of the ordinate of the associated point on the curve i . From this it follows that in order to achieve the pressure levels I, II; "III, etc. within the briquette press cylinder, the setting must be selected according to the pressure levels I ', II', IIP, etc., which approach the curve /; each of the In the illustrated embodiment, the pressure stages associated with curve i is four times greater than the corresponding pressure stage that belongs to curve /, while the duration of these pressure stages that correspond to one another is the same.

The setting of the various pressure levels by hand appears to be considerate

ruled out that due to the short time intervals with which the pressure levels are set one after the other, proper regulation cannot take place; the Correct operation of the machine would depend on the ability and diligence of the sia supervising worker. For this reason, a machine control is used Activation of the various pressure levels

ίο according to very specific, getting smaller and smaller Periods necessary. Such a machine control can be used regardless of whether the. hydraulic drive of the machine system directly takes place by pumping or with the inclusion of multipliers or accumulators.

The control of the individual pressure levels, d. H. the activation of a further stage of a very specific pressure level, after the previous lower pressure level a has lasted a certain amount of time, can be automatic, inevitable or non-positive take place.

An expedient embodiment consists in the closure organs, their lines to the multipliers, accumulators, which have different pressures and the like lead, inevitably to keep open and due to the overpressure the next to close automatically at a higher pressure level. The compulsory control can either using cams seated on a control shaft, which the valve spindles affect, take place, or using a control linkage that of a cam groove a rotating disc is influenced or in some other way.

The way in which the automatic opening and keeping open and the automatic closing of the valves takes place can be seen from the schematic FIG. 2 of the drawing. The control cam V of the pressure curve / mediating control member lifts the associated valve so that the first pressure stage is switched on, while the closing members associated with the other pressure stages are kept closed by spring force or forced. As soon as the time period determined for pressure stage I ', which can be read from FIG. 1, expires, the control cam, which belongs to pressure stage II', opens the relevant closing element in an inevitable manner, resulting in an increased pressure in the hydraulic pressure Press leading line, which presses the still open closing organ of pressure level V on its seat. The closing of the closing element belonging to pressure stage V can, however, also take place inevitably; the valve clearance is repeated in the same way when the following pressure levels are opened.

The number of pressure levels to be used depends on the air content of the Material, its porosity, its specific density, and also of particular physical properties Properties of the material to be pressed, on the size and shape of the one to be produced Pressed pieces, etc.

The time within which the maximum pressure to be selected for a specific material is to be reached is generally to be selected according to the same criteria; , it arises, however, when using a single machine, the pressure and briquetting ⁷ ^ tion of different types of materials to be made, from the dimensions of the machine itself, in particular the size ratio between the ram and the hydraulic piston, the further from the design of the control members or . Driving means for the same, etc.

So if the duration of the compression and maximum pressure is determined in this way, so it is the number of pressure levels by which an approximation to the ideal curve should be made possible. However, it must be taken into account here that for practical and structural reasons, the number of pressure levels is not one can become high, although this is theoretically desirable; because with increasing The number of pressure levels increases, the number of lines, the number of closing organs, the number of controls for the latter, the number of multipliers, etc. It will therefore in practice, an approximation of the ideal pressure curve only through several pressure levels be effected.

When performing the procedure, for the purposes of venting, the already known sliding molds are expediently used or against each other acting ram, which the latter cause a double-sided pressing; through this the venting process is promoted and accelerated.

When using a single machine system for briquetting and pressing different Substances are required according to the maximum pressure to be selected and according to the air content of the material to be pressed the number of pressure levels, their level and the period of time within which they act, to be able to adjust. The setting of the number of pressure levels is made by shut-off devices allows, through which those pressure levels that are not 'to be used, can be completely switched off. The regulation of the duration of the iao

The coming pressure levels take effect by adjusting the lever length of the control elements or by adjusting the control cams, if necessary their replacement 5 or by replacing and inserting Cam disks, if the valves are automatically controlled in this way.

A machine suitable for carrying out the method is illustrated in an exemplary embodiment in FIGS. 3 and 4. Fig. 3 shows an A ^ orderansicht together with a partial section of the hydraulic press and the control housing,

4 shows the side view of the control housing alone.

The briquette press is designed in a known manner in the form of a forming table b which is rotatable about a vertical axis a and which carries the compression molds p. The drive of the press table b takes place in that the same is provided on its underside with bevel gear teeth c , which mesh with a bevel gear d . The latter experiences a drive as long as the two halves f, f of a dog clutch are in engagement; the driving member / 'of the dog clutch is wedged onto a shaft e , which is driven by worm gear drive g. The coupling sleeve of the driving member / 'of the coupling is designed as a spur gear h which meshes with a spur gear ν wedged on a shaft k . As a result, the rotary movement ″ of the shaft e is continuously transmitted to the shaft k and from there to two disks I and s, the former at the end facing the briquette press and the latter at the end of the shaft k facing the control housing ζ .

The disk / carries on its one end face a cam track, against which a roller seated on a vertical pin in a locking slide η is pressed by spring force. The latter engages with its front end in a recess on the circumference of the molding table b as soon as the cam track of the disk / a movement of the roller m allows radial to the molding table (see position of FIG. 3).

The control disk 5 is equipped on its end face (see Fig. 4) with a guide groove t in which a pin attached to the free end of a lever arm χ receives guidance ". The lever χ is wedged on the Steuerwclle u , on which in the illustrated embodiment double lever to sit, which inevitably y with their free ends the spindles of the 'in the control housing ζ move accommodated valves. the number of accommodated in the control housing 2 \ ^ alves is in the illustrated embodiment, six of which two each in one on the control shaft u vertical plane are arranged one behind the other and are moved by a single double lever w .

The control of the closing organs located in the housing s for the working water of the briquette press takes place in such a way that the opening of the same can only occur when the forming table b is at a standstill, ie when the clutch f, f (see FIG. 3) is switched off; here the coupling half / and the bevel gear d, as well as the forming table b, are stationary, while the other coupling half f, the spur gear drive h, ν and the shaft k continue to rotate. The cam disk / assumes the position shown in FIG. 3, in which the roller m and accordingly the locking slide η under the action of the spring 0 move against the molding table; Here the free end of the locking slide η engages in a recess "of the forming table i" and causes it to be held securely in such a position that the filled mold comes into the range of action of the ram or ram r . The lever arm χ engages at the same time that part of the grooved track t in which an oscillating movement of the control shaft u is caused in the sense of a step-by-step opening of the individual control valves; for this purpose the double levers w must of course be wedged onto the control shaft u or the length of the valve spindles y must be set in such a way, that the control valves are opened one after the other within very specific periods of time so that always higher succession pressure stages of the working water are turned on. the closing of the control element of the preceding pressure stage can in this case "done either positively when the valves to the associated spindles y are rigidly connected, or automatically by the fact that the Dr The next higher stage presses the valve back onto its seat.

The working water is led from the control cylinder s under the working piston with gradually increasing pressure. As soon as the briquetting process is finished, the disk / acts with its cam track on the rollers in such a way that the locking slide η emerges from the relevant recess on the circumference of the forming table b and releases the same for further rotation. The claws of the coupling halves / ', /' come into engagement again automatically, the bevel drive d, c is entrained and the forming table accordingly rotates until the

The next filled form comes into the area of the ram r. The press table is in turn determined in the manner already indicated by the locking slide η , the two halves /, / 'of the coupling are automatically switched off by the inclined faces of the coupling claws, and the control elements for the working water are gradually opened again.

Claims (2)

Patent Claims: i. Procedure for briquetting and pressing with complete ventilation of the material to be pressed by applying several pressure levels, characterized in that the pressure level and the pressure duration each stage is adapted to the respective air content of the pressed material in such a way that with decreasing air content either the pressure increase increases in the same times or the duration for the same Pressure increases decreases. 2. Device for performing the method according to claim 1, characterized in that that on a press machine, in which several pressure levels can be switched on in a known manner, for movement " one or more control organs installed in the closing elements dominating the various pressure lines which cause the pressure change sequence applicable to a given material to be pressed. 1 sheet of drawings.