EP4108623A1 - Press and injection element for a press - Google Patents

Abstract

A press serves to lift and/or support and/or prestress an object (8a, 8b) and has a first pressing element (2a) and a second pressing element (2b) which are arranged in such a way that between the first pressing element (2a) and the second pressing element (2b) is formed with a space (4) designed to accommodate a fluid. The first and the second pressing element (2a, 2b) each have a peripheral edge (5) and the edge of the first pressing element (2a) and the edge of the second pressing element (2b) are connected to one another without a bulge.

Description

The present invention relates to a press for lifting and/or supporting and/or prestressing an object and an infeed element for such a press.

Such presses are also referred to as flat presses and are used, for example, to prestress columns, beams or wall panels, or to compensate or correct settlements, for example when underpinning individual foundations, parts of buildings or entire buildings.

A schematic example of a press according to the prior art is shown in FIGS Figures 4a, 4b and 4c shown. Figure 4a shows a cross-sectional view of the press 100 in an unfilled state, ie before filling with a fluid, Figure 4b shows the press 100 in the cross-sectional view according to FIG Figure 4a after filling with a fluid, and Figure 4c shows the press 100 in top view.

The in the Figures 4a-4c The press 100 shown comprises an upper plate 101 and a lower plate 102 which are connected to one another at their edges via a bead 103. The top plate 101 and the bottom plate 102 are shown in plan view (see Fig. Figure 4c ) each circular and the bead 103 is provided circumferentially on the edges of the plates 101, 102. A space 104 is formed between the upper plate 101 and the lower plate 102, which is delimited laterally by the bead 103 and is suitable for receiving a fluid. To introduce the fluid into the space 104 is in the Figures 4a-4c not shown inlet nozzle of the press 100 is provided.

By introducing the pressurized fluid into the space 104, the distance between the plates 101 and 102, ie the height of the space 104, is increased from a first distance a1 in the unfilled state of the press 100 (see Fig. Figure 4a ) to a second distance a2 when the press is filled ( Figure 4b ) enlarged. The difference between the second distance a2 and the first distance a1 is also called Designates stroke or lifting capacity of the press. Typically, the lifting capacity of such a prior art press may be, for example, 25mm.

The height b of the bead 103 of the press 100 specifies an installation height of the press which, for example, a slot in masonry must have at least in order to be able to introduce the press 100 into the slot. Thus, the in Figures 4a-4c Press shown a minimum installation height to be observed, which is typically greater than 25 mm and specified by the height of the beaded edge. In addition, such presses with an edge bead are usually limited to a substantially round shape of the plates forming the top and bottom.

It is therefore an object of the present invention to provide an alternative and/or improved press which, in particular, has a reduced installation height in the unloaded state and/or can have a pressing surface that deviates from a round shape and/or can have a larger pressing surface.

The object is achieved by a press according to claim 1 and an introduction element according to claim 15. Further developments of the invention are specified in the dependent claims. The introduction element can also be further developed by the features of the press set out below or in the dependent claims and vice versa.

A press according to the invention serves to lift and/or support and/or prestress an object and has a first pressing element and a second pressing element which are arranged in such a way that a space designed to receive a fluid is formed between the first pressing element and the second pressing element is. The first and the second pressing element each have a peripheral edge, and the edge of the first pressing element and the edge of the second pressing element are connected to one another without a bead.

The connection of the two pressing elements at their edges does not necessarily have to be provided over the entire extent of the edges; for example, a region of the edges can be left free from the connection, at which an inlet of the press, which serves to introduce the fluid, is provided. The room of the press is also referred to as the press room or interior of the press.

Due to the bead-free connection of the two pressing elements, the press can, for example, be flatter in a state in which it is not filled with the fluid, i.e. have a smaller height extension in a direction perpendicular to the first and/or second pressing element than a press , which is formed with a bead. A bead is to be understood in particular as a thickening of the press in its height direction, i.e. perpendicular to the first and/or second pressing element. Overall, the bulge-free design of the press makes it possible to provide a press with a reduced installation height, for example. Furthermore, the press can thereby be designed, for example, with a pressing surface that deviates from a round shape and/or a larger pressing surface can be provided.

A total height of the press when the space is essentially fluid-free is preferably less than 10 mm, more preferably between 3.5 mm and 7 mm. The overall height of the press is to be understood in particular as a maximum extension of the press between the outer sides (i.e. the sides facing away from the space of the press) of the two pressing elements. The overall height of the unfilled press is also referred to as the installation height.

The first and the second pressing element are preferably designed essentially as flat metal sheets. The design of the pressing elements as essentially flat metal sheets can relate in particular to a state of the press in which the space in the press is essentially fluid-free. "Essentially fluid-free" means here and below that the fluid to be introduced into the space of the press during operation of the press is not present in the space, or in such a small amount that it does not cause any pressure build-up in the press. "Fluid-free" therefore does not exclude the space being filled, for example, with a gas, e.g. air, or a liquid to such an extent that the Gas or the liquid causes no pressure build-up. The "fluid-free" space is also referred to here as the unfilled state of the press. The design of the pressing elements as essentially flat metal sheets in the unfilled state does not therefore preclude the metal sheets from assuming a shape that deviates from a flat shape when the chamber of the press is filled with the fluid, for example bulging or assuming a cushion shape or deforming in some other way.

The design of the pressing element or elements as essentially flat metal sheets in the fluid-free state of the press can, for example, favor a particularly flat design and thus a low installation height of the press.

Preferably, the space extends perpendicularly to the first and/or second pressing element over a height which is at a maximum in a central region of the space when the space is essentially fluid-free. More preferably, the height of the space decreases, even more preferably monotonically, from the central region to lateral regions of the space when the space is essentially fluid-free. Lateral areas of the space can in particular be areas close to the edges of the pressing elements or areas adjoining them. By reducing the height toward the lateral areas, a press can be provided, for example, which—in contrast to a press designed with an edge bead—has its maximum height dimension in a central area. This can, for example, simplify the installation process of the press, e.g. inserting the press into a gap in masonry.

Preferably, the first and the second pressing element have a substantially identical geometric shape, preferably a rectangular or square shape. In this way, for example, good power transmission from the press to the object can be achieved.

Preferably, the edge of the first pressing member and the edge of the second pressing member are welded together. By welding, for example, a connection of the pressing elements can be provided which, on the one hand, is easy to produce in production, and, on the other hand, is very strong and good Tightness, in particular with respect to the fluid to be introduced into the press during operation.

A first maximum height of the essentially fluid-free space is preferably less than a second maximum height of the space that can be achieved by introducing the fluid. This can have the result, for example, that the overall height of the press in the fluid-free state is lower than when the press is in the filled state. Thus, for example, by filling the press, a force can be exerted on the object in a simple manner.

The press preferably further comprises an introduction element for introducing the fluid. It is thus possible, for example, in a simple manner to introduce the fluid into the space of the press during operation of the press. For this purpose, the introduction element can be connected, for example, to a fluid supply or a fluid source. More preferably, the inlet element has a first channel section with a first cross-sectional area and a second channel section with a second cross-sectional area, the second channel section adjoining the space of the press, preferably adjoining it directly, and the second cross-sectional area is larger than the first cross-sectional area. As a result, for example, the fluid can be introduced into the space of the press under greater pressure. The cross section of the first and/or second channel section can in particular be a cross section running perpendicularly to a longitudinal extent of the introduction element and/or to a flow direction of the fluid.

Alternatively or additionally, the introduction element preferably has a recess for receiving the first and second pressing element therein, the recess preferably being designed in the form of a slot. This makes it possible, for example, to connect the introduction element to the press elements in a simple manner, for example to weld them. The recess, in particular a slot-shaped recess, can, for example, allow a certain flexibility of the introduction element in order to follow a deformation of the press or the pressing elements when the space of the press is filled with the fluid.

Preferably, the press further comprises a distribution element provided in the space to even out the spread of the introduced fluid in the space, wherein the distribution element is more preferably designed as a wire and/or wherein the distribution element more preferably has an opening facing an inlet of the press is, through which the fluid can be introduced into the space, in particular wherein the distribution element is essentially V-shaped or U-shaped or omega-shaped. By providing the distribution element, it is possible, for example, to achieve the most uniform possible distribution of the inflowing fluid in the space and thus the most uniform possible deformation or expansion of the two pressing elements.

The fluid is preferably water, or a water-glycol mixture, or a cement suspension. In this way, for example, inexpensive fluids can be provided for operating the press. When using a cement suspension, this can also remain in the press, for example, in order to serve to support the object after hardening.

Preferably, the first and second pressing members are formed of metal. In this way, for example, a robust and at the same time cost-effective material can be provided for the pressing elements.

The press preferably further comprises a drive for introducing the pressurized fluid into the space of the press, the drive preferably being a hydraulic drive. The drive is preferably connected to a fluid source which contains the fluid to be introduced into the press. By means of the drive, for example, a high pressure of the fluid to be introduced into the space of the press or working pressure of the press can be achieved, which in particular can lead to a large force being exerted by the press on the object.

An introduction element according to the invention is used for a press for lifting and/or supporting and/or prestressing an object, the press having a first pressing element and a second pressing element which are arranged in such a way that between the first pressing element and the second pressing element there is a Fluid-trained space is formed, and the introduction element to Introduction of a fluid is formed in the space of the press. The inlet element has a first channel section with a first cross-sectional area and a second channel section with a second cross-sectional area, the second channel section adjoining the space of the press, preferably adjoining it directly, and the second cross-sectional area is larger than the first cross-sectional area. The introduction element according to the invention can be provided, for example, for use with a press as described above. The introduction element according to the invention can, for example, make it possible to achieve a high working pressure of the press.

Fig. 1a

ist eine schematische Ansicht einer Presse gemäß einer Ausführungsform der vorliegenden Erfindung in Draufsicht, Fig. 1b ist eine schematische, im Schnitt dargestellte Ansicht der in Fig. 1a gezeigten Presse senkrecht zu den Presselementen und Fig. 1c ist eine schematische, im Schnitt dargestellte Ansicht der in Fig. 1a gezeigten Presse parallel zu den Presselementen,

Fig. 2

ist eine schematisch, perspektivische Ansicht eines Einleitelements gemäß einer Ausführungsform der vorliegenden Erfindung,

Fig. 3a und 3b

sind schematische, im Schnitt dargestellte Ansichten der in Fig. 1a-1c gezeigten Presse im Betrieb, wobei Fig. 3a die Presse in einem unbefüllten Zustand zeigt und Fig. 3b in einem befüllten Zustand, und

Fig. 4a-4c

sind schematische Ansichten einer Presse gemäß dem Stand der Technik, wobei Fig. 4a und 4b die Presse im Schnitt und im unbefüllten Zustand (Fig. 4a) bzw. im befüllten Zustand (Fig. 4b) zeigen, und Fig. 4c die Presse in Draufsicht zeigt.

Further features and advantages of the invention result from the description of exemplary embodiments with reference to the accompanying drawings.

Fig. 1a

Fig. 12 is a schematic plan view of a press according to an embodiment of the present invention, Fig. 1b is a schematic sectional view of FIG Fig. 1a shown press perpendicular to the pressing elements and 1c is a schematic sectional view of FIG Fig. 1a shown press parallel to the pressing elements,

2

is a schematic, perspective view of an introduction element according to an embodiment of the present invention,

Figures 3a and 3b

are schematic sectional views of the Figures 1a-1c press shown in operation, wherein Figure 3a shows the press in an unfilled state and Figure 3b in a filled state, and

Figures 4a-4c

are schematic views of a press according to the prior art, wherein Figures 4a and 4b the press in section and in the unfilled state ( Figure 4a ) or when filled ( Figure 4b ) show, and Figure 4c shows the press in plan view.

The following is with reference to Fig. 1a-c an embodiment of the present invention is described. In the Figures 1a-1c The press 1 shown has a first pressing element in the form of a first plate 2a and a second pressing element in the form of a second plate 2b, as well as an introduction element in the form of an inlet connection 3. The inlet connection 3 is connected to a drive 10, in particular a hydraulic drive, which can be connected to a fluid source, not shown, in order to introduce a pressurized fluid through the inlet port 3 into the space 4 of the press 1.

In the present embodiment, the first metal sheet 2a and the second metal sheet 2b are each rectangular and congruent with one another. The first metal sheet 2a forms an upper side of the press 1 and the second metal sheet 2b forms an underside of the press 1. For example, the metal sheets 2a and 2b can be designed as essentially flat plates. A thickness of the metal sheets (not shown in the figures) can be a few millimeters, for example between 1.5 mm and 2.0 mm. The sheets 2a and 2b can, for example, be made of a metal or an alloy, i.e. they can be realized, for example, as commercially available steel sheets (e.g. in quality S235).

The metal sheets 2a, 2b each have peripheral edges 5 and are connected to one another at their edges 5, for example welded to one another. No bead is formed between the metal sheets 2a, 2b, ie they are connected to one another without a bead. In an area of an inlet 4a (s. 1c ) of the space 4, the edges 5 of the metal sheets 2a, 2b are excluded from the connection in the present embodiment. Between the first sheet 2a and the second sheet 2b there is an intermediate space or cavity 4, referred to below as space 4, which is designed to receive the fluid. The fluid (not shown in the figures) can be introduced into the space 4 through the inlet connector 3 . For this purpose, the inlet nozzle comprises at least one cavity, for example a bore, which connects a fluid source (not shown) to the inlet 4a (see Fig. 1c ) of the space 4 fluidly connects. In particular, the inlet nozzle 3 according to a further below in relation to 2 described inlet pipe 13 may be formed.

The space 4 extends perpendicularly to the metal sheets 2a, 2b over a height h (see Fig. Fig. 1b ). Since the sheets 2a, 2b are connected to each other without a bulge, the height h of the space 4 is maximum in a central area and decreases towards the edges 5 of the sheets 2a, 2b, i.e. to the lateral areas of the space 4, when the space 4 is essentially fluid-free or not filled. A total height of the press thus results from the sum of the height h of the space 4 and the thicknesses of the metal sheets 2a, 2b. Since the thickness of the sheets 2a, 2b is not shown in the figures, the overall height of the press in the schematic view corresponds to that Figure 1b the height h of the space 4. The maximum extension of the press 1 between the outer sides of the two metal sheets 2a, 2b, ie the overall height or installation height of the press 1, can be in the range of a few millimeters, in particular less than 10 mm, for example 5 mm .

Optionally, a distribution element in the form of a wire 6 (see Fig. 1c ) intended. In the present embodiment, the wire 6 is formed in an omega shape, with the opening 6a of the omega shape facing the inlet 4a of the press 1 . The wire 6 is in 1c spaced on all sides from the edges 5 of the sheets 2a, 2b. For example, before the two metal sheets 2a, 2b are welded together, the wire 6 can be placed between them and clamped between the metal sheets 2a, 2b. The wire 6 can have a diameter of less than 1 mm, for example, in particular between 0.5 mm and 0.8 mm.

The fluid intended for use with the press 1 can be, for example, water, or a water-glycol mixture, or a cement suspension.

The following is with reference to 2 an inlet nozzle 13 according to the present invention is described. The inlet port 13 can in particular as the inlet port 3 of the above with respect to Figures 1a-1c Press 1 described can be used.

The inlet port 13 extends from a first end 13a to a second end 13b and in the present embodiment is of a substantially cylindrical shape Outer shape formed. At its second end 13b, the inlet connection piece 13 has a slot-shaped recess 14, which is designed for fastening the inlet connection piece 13 to the press 1. In the present embodiment, the recess 14 for receiving the interconnected metal sheets 2a, 2b is formed therein. For this purpose, the inlet connector 13 can, for example, with its recess 14 over the metal sheets 2a, 2b of the press 1 in the area of the inlet 4a (see Fig. 1c ) pushed over the two sheets 2a, 2b and then welded to the sheets 2a, 2b.

Furthermore, the inlet connection 13 has an internal channel which extends from the first end 13a in the direction of the second end 13b and in the recess 14 or the inlet 4a of the press 1 (see Fig. 1c ) ends. The channel is formed from a first section 15, for example a first bore, and a second section 16, for example a second bore. The second section 16 preferably extends essentially over half the length that the inlet connector 13 has from its first end 13a to the second end 13b. The first section 15 of the channel is provided at the first end 13a of the inlet connection 13 and has a smaller cross-sectional area than the second section 16 of the channel, which opens into the recess 14 . in the in 2 In the embodiment shown, the first and second sections 15, 16 of the channel are each designed as cylindrical bores which are coaxial with one another and coaxial with the cylindrical shape of the inlet connection 13, with a first diameter d1 of the first section 15 being smaller than a second diameter d2 of the second Section 16.

Furthermore, the inlet connector 13 has on its outside at the first end 13a, ie the end 13a facing away from the press, a fastening device in the form of a thread 17 for fastening the inlet connector to a fluid source or the drive 10 (not shown in the figures) (see Fig. Fig. 1a ).

The following is with reference to Figures 3a and 3b and the previous figures describe an example of a use of the press 1 described above. In the example of Figures 3a, 3b is the press 1 for widening a gap 7 in a masonry between a first wall section 8a and a second Wall section 8b is formed used. The gap 7 has a height H1 as the distance between the two wall sections 8a, 8b (see Fig. Figure 3a ), which is greater than or equal to a maximum extension of the press 1 between the outer sides of the two sheets 2a, 2b (total height or installation height of the press 1). As in Figure 3a the press 1 is shown inserted into the gap 7 in such a way that the first metal sheet 2a faces the first wall section 8a and the second metal sheet 2b faces the second wall section 8b.

Then, using drive 10 (see Fig. 1a ) a pressurized fluid from a fluid source (not shown) is introduced into the space 4 of the press 1 through the inlet connection 3 or 13 . The optional wire 6 achieves a distribution of the inflowing fluid in the space 4 that is as uniform as possible. The height h of room 4 (s. Fig. 1b ) and thus also the overall height of the press 1 and the two metal sheets 2a, 2b exert pressure on the adjacent wall sections 8a, 8b. As a result, a force is exerted by the press 1 on the wall sections 8a, 8b, which causes the height of the gap 7 between the wall sections 8a, 8b to increase. In Figure 3b the height H2 of the gap when the press 1 is filled with fluid is greater than the height H1 of the gap (see Figure 3a ) when press 1 is not filled. Purely as an example, press 1 can be operated at a working pressure of 150 bar (1.5 kN/cm ² ) and have an area of 1600 cm ² , for example, so that the press generates a force of 2400 kN can be exerted on the masonry. The stroke, ie the lifting capacity of the press 1, can be 30 mm, for example.

The wall sections 8a, 8b exert a counter-pressure on the metal sheets 2a, 2b, which can have the effect, for example, that the metal sheets 2a and 2b remain essentially parallel at least in a central area of the press 1 and thus in particular the pressure generated by the inflowing fluid as evenly as possible to the masonry. Without such a counter-pressure from the masonry, the metal sheets 2a, 2b could deform, for example in the form of a cushion, due to the introduced fluid.

The present invention is not related to the above Figures 1a-3b described embodiment limited. Further developments of the press 1 and the inlet connection 13 are possible within the scope of the present invention.

For example, the pressing elements of the press can deviate from the rectangular shape shown in the figures when viewed from above and can, for example, have a square, oval or round shape. In principle, any geometric shape of the pressing elements is possible, but the pressing elements preferably have a shape without concave, i.e. re-entrant corners.

Furthermore, the press 1 can also be provided with an inlet connection other than that referred to in FIG 2 described inlet nozzles are used, and with reference to 2 Inlet connection 13 described can also be used with presses other than those referred to in FIG Figures 1a-1c and 3a, 3b described press can be used, for example with the reference to Figures 4a-4c described press.

Furthermore, the wire 6 may deviate from an omega shape; for example, the wire can be U-shaped, V-shaped or have any other shape favoring an even distribution of the fluid in the space of the press. The press can also have a distribution element that differs from a wire or can be designed without a distribution element.

Claims (15)

Press for lifting and/or supporting and/or prestressing an object (8a, 8b), wherein
the press (1) has a first pressing element (2a) and a second pressing element (2b), which are arranged in such a way that between the first pressing element (2a) and the second pressing element (2b) there is a space (4) designed to accommodate a fluid is formed, characterized in that
the first and the second pressing element (2a, 2b) each have a peripheral edge (5) and the edge of the first pressing element (2a) and the edge of the second pressing element (2b) are connected to one another without a bulge. Press according to Claim 1, in which the first and the second pressing element are essentially designed as flat metal sheets (2a, 2b). A press according to claim 1 or 2, wherein the space (4) extends perpendicularly to the first and/or second pressing member (2a, 2b) over a height (h) which is maximum in a central portion of the space when the space is substantially is free of fluid. Press according to Claim 3, in which the height (h) of the space (4) decreases, preferably monotonically, from the central region towards lateral regions of the space when the space is essentially fluid-free. Press according to any one of claims 1 to 4, wherein the first and the second pressing element (2a, 2b) have a substantially identical geometric shape, preferably a rectangular or square shape. Press according to one of claims 1 to 5, wherein the edge (5) of the first pressing element (2a) and the edge (5) of the second pressing element (2b) are welded to one another. 7. The press of any one of claims 1 to 6, wherein a first maximum height of the substantially fluid-free space is less than a second maximum height of the space achievable by introducing the fluid. Press according to one of Claims 1 to 7, further comprising an introduction element (3, 13) for introducing the fluid. Press according to claim 8, wherein the introduction element has a first channel section (15) with a first cross-sectional area and a second channel section (16) with a second cross-sectional area, the second channel section (16) adjoining the space (4) of the press (1). , preferably directly adjoining it, and wherein the second cross-sectional area is larger than the first cross-sectional area. Press according to Claim 8 or 9, in which the introduction element (13) has a recess (14) for receiving the first and second pressing element (2a, 2b) therein, the recess (14) preferably being in the form of a slot. Press according to one of Claims 1 to 10, further comprising a distribution element provided in the space (4) to even out the spread of the introduced fluid in the space, the distribution element preferably being in the form of a wire (6) and/or the distribution element preferably being in the form of a wire (6). has an opening (6a) facing an inlet (4a) of the press (1) through which the fluid can be introduced into the space, in particular wherein the distribution element is essentially V-shaped or U-shaped or omega-shaped . Press according to any one of claims 1 to 11, wherein the fluid is water, or a water-glycol mixture, or a cement suspension. A press according to any one of claims 1 to 12, wherein said first and second press members (2a, 2b) are formed of metal. Press according to one of Claims 1 to 13, further comprising a drive (10) for introducing the pressurized fluid into the space (4) of the press (1), the drive preferably being a hydraulic drive. Introductory element for a press for lifting and/or supporting and/or prestressing an object, the press (1) having a first pressing element (2a) and a second pressing element (2b) which are arranged in such a way that between the first pressing element (2a ) and the second pressing element (2b), a space (4) designed to receive a fluid is formed, and the introduction element (13) is designed to introduce a fluid into the space (4) of the press,
wherein the introduction element (13) has a first channel section (15) with a first cross-sectional area and a second channel section (16) with a second cross-sectional area, the second channel section (16) adjoining the space (4) of the press (1), preferably directly adjoins it, and the second cross-sectional area is larger than the first cross-sectional area.

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