DE924479C - Hydraulic lifting device with parts that can be telescoped into one another - Google Patents

Description

Hydraulic lifting device with telescoping one inside the other Parts In hydraulic lifting devices, cylinders are mostly telescopic telescopic piston used. While it is the inner piston is a piston in the usual sense, are the others surrounding it Piston designed as a ro-shaped slide. Each of the pistons has an annular shape provided, which is provided with a corresponding projection of the piston surrounding it or of the cylinder cooperates. In addition, each piston w6st a further ring-shaped Stop, which is supported on the next piston when the piston is pushed back.

When such a telescopic piston is applied, all Pistons raised together by the pressure medium. Because here the entire the inside diameter of the cylinder corresponding surface is effective as a pressure surface, is used for lifting the load a relatively large amount of pressure medium at a relatively low one Pressure needed. Now hits the outer cattail with its limit stop on the corresponding stop of the cylinder, this will be the cattail from there on prevented from further upward movement. Infoligede @ ssen is now a smaller one Circular area effective as a lifting pressure area, so that from now on wendger pressure medium, but with higher pressure, required for further upward movement of the load is. Depending on the number of cattails present, it is repeated over the course of the Lifting process the gradual increase in pressure as the amount of pressure medium decreases several more times until finally the innermost piston still alone moved on. The smallest pressure area is effective, so that relatively Little pressure medium with very high pressure for further lifting (the load required is.

The described operation of the known telescopic piston .en requires for -the loading of the Hulbvorri.chtun@g a pump, which on the one hand the to At the beginning of the lifting process, the greatest delivery rate required and, on the other hand, serve on At the end of the lifting process, provide the very high pressure required with a small delivery rate can. In order to meet these requirements, multi-piston pumps have been built that switched to a smaller delivery rate by gradually switching off individual pistons and with the same drive power, a step-by-step increase Deliver pressure. Such pumps are complex and expensive. aside from that the efficiency of such pumps is of course relatively poor.

Another disadvantage of the 'known telescopic pistons is that! The transition from one level to the other results in a level, albeit a relatively short one can not be avoided, so that the load is not lifted completely evenly. This disadvantage is extremely disadvantageous when tipping ladles, for example noticeable, thereby the jerky vibrations when transitioning from a step on the other hand, the slag layer covering the liquid metal is shaken and can tear, so that together with the liquid metal slag enters the casting molds got.

The invention has for its object to provide a hydraulic lifting device riding telescope-like telescoping parts in which the above-mentioned disadvantages of the known Hubvorricihtungen are avoided; In particular, the invention is intended to achieve a completely uniLye Hu'bbeweL-unLr, whereby also for the A ri eh fl-pt ' required The lifting process is the same size @ ble @ nbt ui mi s arn ia the same pressure is to be supplied, so that a pump can be used for a constant flow rate at constantly the same pressure "which has a" very good efficiency " .A differential piston executed on its larger flee, acted upon by the hydraulic pressure generator first reciprocating piston during the working stroke by means of its smaller piston surface a closed pressure fluid volume, which thereby .lifts the second piston.

In the lifting device according to the invention, the larger piston area : of the first reciprocating piston with pressure medium, designed in the manner of a differential piston acted upon by the pump. The smaller piston area of this reciprocating piston acts on a closed amount of pressurized fluid, which at the displacement = ung of the first reciprocating piston is displaced and to act on a second reciprocating piston serves, so that also this versdhnben ryvixd. A particularly simple one and the one so far A construction similar to the usual construction results when the second reciprocating piston is in the piston rod designed as a cylinder of this first reciprocating piston is displaceable.

By appropriate choice of the area ratio between the smaller Piston surface of the first reciprocating piston and the associated piston surface of the second HUbkdlbens can turn @ that the hydraulic fluid coupling the two reciprocating pistons works like a transmission gear and the second reciprocating piston faster or is moved more slowly compared to the first reciprocating piston than this reciprocating piston his top hat. A particularly advantageous embodiment is obtained when the area ratios be chosen so (that the smaller piston area of the first piston piston and the associated piston surface of the second reciprocating piston have the same size. The smaller one Piston surface, the first is advantageously made about half as large as its larger cabin area.

For filling the one above the smaller piston area of the first reciprocating piston and space with pressure medium, which is located under the piston surface of the second reciprocating piston a pressure medium is expediently in the first reciprocating piston. the side of the larger Integrated backflow valve to the side of the smaller piston area.

The principle according to the invention can of course also be used in lifting devices with more than two reciprocating pistons which can be telescoped into one another. If, for example, three displaceable reciprocating pistons are to be designed so that the advantages of the invention are achieved, the second reciprocating piston is also designed in the manner of a differential piston which works on the third reciprocating piston by means of pressure fluid displaced by its smaller piston surface. In this case, the second reciprocating piston will also not work will. . The application of the invention is in no way restricted to purely hydraulic lifting devices; rather, the stated principle can also be used to advantage in lifting devices actuated by compressed air. In such a case, the first reciprocating piston of the lifting device is not acted upon by pressure fluid, but rather connected to an auxiliary piston that can be acted upon by compressed air. In this case, the second reciprocating piston which can be displaced in the first reciprocating piston results in a double stroke movement with a single stroke of the auxiliary piston acted upon by compressed air. With such a compressed air-operated lifting device, it is of course also possible to apply pressure fluid to the first piston so that the lifting device can be driven either with pressure fluid or compressed air or with both pressure media at the same time. Embodiments of the invention are shown in the drawing, namely Fig. 1 shows a telescopic jack with two reciprocating pistons, Fig. 2 shows a telescopic jack with three reciprocating pistons and Fig. 3 shows a telescopic jack corresponding to Fig. I with one with the first reciprocating piston connected auxiliary piston that can be acted upon by compressed air.

In the Awsführungg'beispiel according to Fig. I is in a cylinder i, which has a pressure medium supply line 2, a reciprocating piston 3 displaceable, which after Type of a differential piston is carried out. q. is the one designed as a cylinder Piston rod of reciprocating piston 3, which has a non-return valve in (its lower part 5 and bores 6, through which the existing above the smaller piston area Annular space 7 is connected to the cavity 8 of the cylinder 4. In the upper part the piston rod of the reciprocating piston 3 designed as a cylinder .4 is a second reciprocating piston 9, the old displacement hummingbird is working. The individual tours are natural equipped with the necessary seals.

The function of the lifting device described is as follows: Before the device is put into operation, the cavities 7 and 8 must be finite Pressure medium are filled. For this purpose there must be some kind of outpouring of air at the upper ends of the spaces 7, 8. It will .then over the bore 2 is supplied with hydraulic fluid, which via the check valve 5 into the Rooms 7 and 8. When these spaces are completely filled, the air outlets will open locked. Now the Vorridhtung is ready for use.

If the device is to be used for lifting loads, then through the bore: 2 pressure medium is fed into the cavity of the cylinder i. This pressure fluid device lifts the reciprocating piston 3 and thus presses the pressure fluid present in the space 7. This liquid drains through the bores 6 into the space 8 of the cylinder .I and pushes the displacement piston 9 upwards. Simultaneously with the upward movement of the reciprocating piston 3 there is also an upward movement of the reciprocating piston 9. The speed of the movement of the reciprocating piston 9 against the cylinder 4 depends on the ratio of the annular surface of the reciprocating piston 3 acting on the space 7 to the circular surface of the The piston rod of the piston 9, as already stated at the beginning. If the two piston surfaces are made to be the same size, the reciprocating piston 9 moves at twice the speed in relation to the reciprocating piston 3.

The pressure with which the hydraulic fluid is passed through the bore: 2 = must be, results from the weight of the load to be lifted and the size .der lower piston surface of the reciprocating piston 3. When lifting the load in the spaces 7, 8 prevailing pressure is correspondingly dependent on the weight of the load and the circular cross-section of the reciprocating piston 9. This pressure is because the piston area of the reciprocating piston 9 is significantly smaller than the lower piston surface of the reciprocating piston 3, considerably higher than the pressure of the hydraulic fluid supplied through the bore: 2. While in the case of previously known telescopic lifters, the circular cross section of the reciprocating piston 9 corresponding very high pressure must be supplied towards the end of the stroke movement, the pump only needs a lower one in the device according to the invention To put pressure on. The pump and the supply line to the lifting device therefore need not to be run for as high pressures as before.

In the embodiment according to FIG. 2, in the cylinder i provided with the feed bore 2, the reciprocating piston 3 is in turn displaceable, the piston rod of which is the cylinder q. and (which is equipped with the Rüekschlagven.til5 and the bores 6. In (the cylinder q. in this case a reciprocating piston can be moved, which is designed in exactly the same way as the reciprocating piston 3. ii is the non-return valve, which connect the cavity 8 located below the piston with the above located spaces 12 and 13. 14 is the piston rod of the reciprocating piston designed as a cylinder for a third reciprocating piston 16. The stanchions through which the spaces 12 and 13 are connected to one another are denoted by 1 5.

In this case, when supplying pressure fluid through the bore 2 in the cylinder i of the reciprocating piston 3 moved upwards. This takes place in the first embodiment described way at the same time an upward shift d it reciprocating piston io. The speed of this shift is with .dem according to Fi.g. 2 depending on the ratio of the piston area of the acting on the annular space 7 Hulbkolbens 3 and the lower piston surface of the reciprocating piston io. On its upward movement pushes .the Hubkol'ben OK, the one in the annulus. 12 located liquid and presses this through the bores 15 into the cavity 13 ″ so that the reciprocating piston too 16 in, with respect to .den piston io is moved upwards. The speed this The upward movement depends on the ratio of the forces acting on the annular space 12 Piston area of the reciprocating piston and the area of the circular cross-section of the displacement piston 16.

In this embodiment, prevail during the lifting process in the rooms 7 and 8 on the one hand and 12 and 13 on the other hand different pressures. This results from the fact that those to be lifted put the load on the fluidity of the rooms 12 and 13 pushes with the small circular cross section of the reciprocating piston 16, while the Load on the liquid present in the spaces 7, 8 with the much larger one Circular area, the piston acts io.

In the second exemplary embodiment, too, appropriate Dimensioning of the piston surfaces can be achieved that the reciprocating pistons 3, io and 16 with gradually increasing speed .opposite to move the cylinder i upwards. The total stroke movement takes place without any impact perfectly even.

The embodiment according to FIG. 3 agrees with the first embodiment largely match. There is a difference insofar as with the one executed as a cylinder q .: Koilbenstange the reciprocating piston 3 in this case a reit compressed air beaufsch1agbairer Auxiliary piston 17 is connected, which is displaceable in a compressed air cylinder 18. The compressed air cylinder 18 is structurally combined with the hydraulic cylinder i and has a bore i9 for the supply of the compressed air.

The operation of this apparatus differs from! Of the lifting device according to Fig. I only in that the Hubkollben 3 not by pressure fluid, .but by compressed air by means of the auxiliary piston 17 is moved upward. During the upward movement of the piston 3, the pressure fluid is pressed over from the space 7 into the space 8 in the same way as described above, so that the piston g in the cylinder q. is moved upwards.

As the last embodiment shows, the invention provides Possibility of increasing the overall height of the compressed air cylinder for a given lifting height to reduce the size by using the piston of the compressed air cylinder with a reciprocating piston further telescopically extendable piston is connected, .der with this is hydraulically coupled according to the invention.

Claims (7)

PATENT CLAIMS: i. Hydraulic lifting device with through at least two reciprocating pistons which can be telescoped into one another, characterized in that d @ ate the one designed in the manner of a differential piston, on its larger surface acted upon by the hydraulic pressure generator first reciprocating piston (3) by means of its smaller piston area a closed volume of fluid on the working stroke displaced, which thereby @anheibt the second lifting piston (9). 2. Lifting device according to claim i, characterized in that the second reciprocating piston. (9) in the as Cylinder (q.) Executed piston rod of the first reciprocating piston (3) is displaceable. 3. Lifting device according to claim i and 2, characterized in that the smaller Piston surface of the first reciprocating piston (3) and the piston surface of the second reciprocating piston (9) same size. q .. Lifting device according to claims i to 3, characterized characterized in that the smaller piston area of the first reciprocating piston (3) is approximately half is as large as its larger piston area. 5. Lifting device according to the claims i to q., characterized in that a pressure medium in the first reciprocating piston (3) Check valve passing from the side of the larger to the side of the smaller piston area (5) is built in. 6. Lifting device according to claims i to 5, characterized in that that when using three reciprocating pistons and the second reciprocating piston (io) in the manner of a Differential piston is executed and means of its smaller piston area displaced hydraulic fluid on the third piston (i6) works (Fig.2). 7th Lifting device according to claims i to 6, characterized in that with the first reciprocating piston (3) an auxiliary piston (i7) which can be acted upon by compressed air is connected in this way is that the first reciprocating piston either directly with hydraulic fluid or indirectly can be raised by compressed air.