EP2072188B1 - Press tool with bistable tension mechanism - Google Patents

Abstract

The press tool (2) has two pivoting elements (4a,4b) each having actuating sections (6a,6b) and press sections (8a,8b), which are pivoted around rotary axes (20a,20b) assigned to each of the pivoting elements. Two support elements (16a,16b) are associated with the pivoting elements, which hold both the rotary axes. A clamping unit is formed in bistable manner.

Description

The invention relates to a pressing tool for non-releasably connecting a pipe and a fitting with two pivoting elements each having an actuating portion and a pressing portion, which are pivotable about each pivot axis associated with them, with two support elements associated with the pivot elements, which hold the two axes of rotation, and with a bistable tension mechanism, wherein the inner contours of the opposing pressing portions of the two pivot elements form a receiving area, and wherein the receiving area formed by the inner contours in the first stable state is narrower than in the second stable state.

Pressing tools of the type mentioned are already, for example from the document EP0860245 known. As a tensioning mechanism, for example, a spring arranged between the actuating sections of the pivoting elements is provided which spreads the actuating sections and thus presses the pressing sections against one another at the same time, so that the receiving area narrows. As a spring, for example, a pressure-resilient coil spring is used. In this way, the inner contours of the pressing sections can be brought by spring force into contact with the outer peripheral surface of the pipe or fittings to be compressed or the sleeve to be pressed, before the cold pressing is performed by acting on the operating sections of the pivot elements engine.

If a user wants to use such a pressing tool, he must on the one hand bring the components to be pressed in the position provided for the pressing position and hold there, on the other hand press the actuating portions in a stressing the tensioning mechanism against each other to make the pressing tool for receiving the components ready , and additionally bring the pressing tool and the associated engine in the position provided for the pressing and hold there. There are thus three points on which the user has to pay attention. In practice, the user may, where appropriate, avail himself of the assistance of another person who assumes one of the three aforementioned activities. The user can continue to get rid of the first of the aforementioned activities by using technical aids, for example by fixing the components to be pressed before the pressing tool is applied. However, the user the use of a previously described pressing tool is difficult if he wants to perform the pressing without outside help or without further technical aids, in particular without separate fixation of the components.

The patent EP 0 860 245 A2 discloses a pressing device with a bistable tensioning mechanism, which may be formed with a blocking device, for example in the form of magnets or locking elements.

The DE 34 23 283 A1 discloses a clamping tool having two clamping jaws disposed in a housing and pivotally secured to the housing, wherein return springs are provided between the levers and the housing, and wherein the arrangement of the return springs effects a bistable tensioning mechanism.

The present invention is based on the technical problem of providing a pressing tool which is easier to handle.

According to the present invention, the technical problem is solved by a pressing tool having the features of independent claims 1, 8 or 11.

According to the invention it has been recognized that the handling of a pressing tool of the type mentioned can be simplified if a bistable tensioning mechanism is provided. This means that the voltage mechanism can assume two states that it does not leave again, at least without the action of a pulse. In the first stable state of the tension mechanism, the receiving area is narrower than in the second stable state. This is the case, in particular, when the tension mechanism has completed the greatest possible spread of the actuating sections, so that the abutment surfaces of the pressing sections abut one another. Of course, it is also possible to assume the first stable state if the inner contours of the pressing sections abut against a component located in the receiving region without the abutting surfaces of the pressing sections coming into contact. In the second stable state, the pivot elements are aligned with each other so that the receiving area is further than in the first stable state and thus in particular ready for receiving a component to be compressed, for example, pipe, fitting or sleeve.

The handling of a pressing tool of the type mentioned is simplified for a user by first bringing the tension mechanism in the second stable state in which the pressing tool remains due to the prestressing caused by the tensioning mechanism. With the preselected pressing tool, the user can concentrate solely on the positioning of the components to be pressed and on the positioning of the pressing tool on the components to be pressed. The help of another person or additional, mostly improvised technical aids are no longer necessary. The user can thus insert the component into the receiving area, check the correct position of the pressing sections with respect to the component and then cause a pulse, which causes the tension mechanism to leave the second stable state and the first stable state in which the receiving area is narrower , in particular in which the inner contours rest on the outer peripheral surface of the component. Preferably, the momentum causing the transition from the second to the first stable state to the inner contours of the pressing sections, possibly be effected by the components to be pressed itself. If the inner contours of the pressing sections reliably enclose the components, the user can activate the engine and perform the pressing.

Preferably, the force transmitted in the first stable state by the tensioning mechanism via the inner contours of the pressing sections to the outer peripheral surface of the component is not large enough to already carry out a deformation of the components. In other words, preferably, it is opposite to the tension mechanism of the component Resistance in the first stable state large enough to prevent deformation. The actual compression is then effected only by pressing the engine. In this way, a user of the pressing tool can check the positions of the components and the pressing tool in the first stable state and correct, if necessary, by bringing the clamping mechanism of the pressing tool back to the second stable state, thus widening the receiving area, and re-pressing the pressing sections attached to the components. In this way it is easier for a user to perform a correct compression, because he can devote his attention almost exclusively to the positioning.

The tensioning mechanism has a leg spring arranged between the pivoting elements. Depending on a spring leg can then rest against the mutually facing outer surfaces of the pivot elements and thus ensure optimum transfer of force from the pivot elements on the spring legs and vice versa. In addition, leg springs, usually made of metallic materials, are less susceptible to wear and are available on the market with various properties, such as spring constants and geometric shapes, so that the crimping tool can be designed to meet different requirements by selectively selecting a particular leg spring.

Furthermore, the leg spring is movably mounted relative to the axes of rotation of the pivot elements. In this way, the bias of the tension mechanism can be set very flexible. Preferably, the leg spring is movable along the perpendicular to a connecting line between the two axes of rotation of the pivot elements. It is next preferred that a certain position along the aforementioned vertical corresponds to a certain orientation of the spring legs to each other. In this way, the locking mechanism, which enables a second stable state of the tensioning mechanism, can be very flexibly incorporated into the pressing tool. In addition, the pressing tool can be made very sensitive to various, the transition of the tension mechanism from the second to the first stable state triggering pulses in this way.

In one embodiment of the pressing tool, the tensioning mechanism additionally has a hollow bolt that passes through the turns of the leg spring and two pressure pieces that are spring-mounted at least partially in the bolt. With this arrangement, the relationship between the position of the leg spring along the perpendicular to the connecting line between the axes of rotation and the alignment of the spring legs to each other can ensure particularly reliable. The bolt also ensures that the pivoting movements of the pivoting elements are symmetrical executable. In addition, the bolt provides additional alternatives to transfer the transition of the tensioning mechanism from the second to the first stable state causing impulses to the tensioning mechanism. The resiliently mounted in the bolt plungers make it possible to transfer the locking mechanism of the second stable state of the tensioning mechanism on the swivel elements facing side surfaces of the support elements.

According to the invention, the carrier elements have a reduction adapted to a pressure piece. If an end face of the pressure piece is slid by a movement of the bolt, and Under load of the resilient mounting of the pressure piece in the bolt, guided along the pivot elements facing side surfaces of the support member, the pressure piece can engage in place of the reduction in this. Preferably, the position of the bolt, the corresponding position of the spring and the corresponding orientation of the spring legs to each other, in which the pressure piece engages in the depression, just corresponds to the second stable position of the tensioning mechanism. The transmitted from the tensioning mechanism on the pivot elements force is not sufficient to dissolve the engagement of the pressure piece in the reduction. Rather, an impulse is needed.

In a further advantageous embodiment of the pressing tool at least one arranged on the inner contours of the pressing sections pulse transformer is provided. In this way, the pulse can be effected by the introduced into the receiving area, provided for the compression components. For example, the swivel elements can be provided coordinated panels. The introduced into the receiving area components can then press against the receiving area facing edge of the sheets and so transmit the pulse to the tensioning mechanism. In this way, in particular, a monostable tensioning mechanism having pressing tools can be retrofitted and thus equipped with a bistable tensioning mechanism. Alternatively, however, it is also possible to provide a sliding element which is arranged between the inner contours of the pressing sections and in particular integrated. The sliding element preferably has a side surface adapted to the inner contours of the pressing sections of the pivoting elements. In this way it can be avoided that between the two inner contours during the Verpressungsvorgangs a gap exists, which could result in an asymmetrical, possibly not sufficiently tight pressing result.

Furthermore, the reduction can be arranged in a recess arranged on the carrier element. The recess is particularly suitable for providing the pulse transducers with a guide region. Thereby, the stability of the tension mechanism can be further improved.

According to a further embodiment of the invention, the technical problem is solved in that the tensioning mechanism has a leg spring with legs having angled ends and at least one retaining cam arranged on at least one of the pivoting elements. In this way, the locking mechanism as a structural design on the

Leg spring and are provided on the pivot elements. The number of the voltage mechanism forming components can be kept so low. As a result, the reliability of the pressing tool can be ensured even after many pressing cycles.

Fig. 1a-c

ein Ausführungsbeispiel eines erfindungsgemäßen Presswerkzeugs mit einem Schiebeelement als Impulsübertrager in einer Explosionsansicht und zwei Querschnittsansichten,

Fig. 2a-b

ein weiteres Ausführungsbeispiel des erfindungsgemäßen Presswerkzeugs mit Blechen als Impulsübertrager in einer Explosionsansicht,

Fig. 3a-b

ein weiteres Ausführungsbeispiel des erfindungsgemäßen Presswerkzeugs ohne separaten Impulsübertrager in einer Explosionsansicht,

Fig. 4

ein Ausführungsbeispiel eines weiteren erfindungsgemäßen Presswerkzeugs mit einem der Federtotpunktlage entsprechenden zweiten stabilen Zustand des Spannungsmechanismus in einer Querschnittsansicht und

Fig. 5

Ausführungsbeispiel eines weiteren erfindungsgemäßen Presswerkzeugs mit einer Schenkelfeder, deren Schenkel abgewinkelte Enden aufweisen, in einer Querschnittsansicht.

In the following the invention will be explained in more detail with reference to embodiments illustrated in a drawing. In the drawing show:

Fig. 1a-c

An embodiment of a pressing tool according to the invention with a sliding element as a pulse transformer in an exploded view and two cross-sectional views,

Fig. 2a-b

a further embodiment of the pressing tool according to the invention with plates as pulse transformer in an exploded view,

Fig. 3a-b

a further embodiment of the pressing tool according to the invention without separate pulse transformer in an exploded view,

Fig. 4

an embodiment of another pressing tool according to the invention with a spring dead center position corresponding second stable state of the tension mechanism in a cross-sectional view and

Fig. 5

Embodiment of a further pressing tool according to the invention with a leg spring whose legs have angled ends, in a cross-sectional view.

Fig. 1a shows an embodiment of the pressing tool 2 according to the invention in an exploded view. Two symmetrical pivot elements 4a, 4b are arranged opposite each other in this example. In principle, the pivot elements 4a, 4b may also have a different structural design. The pivot elements 4a, 4b each have an actuating portion 6a, 6b and a respective pressing portion 8a, 8b. Depending on a surface of the pressing portions 8a, 8b has an inner contour 10a, 10b, so that between the inner contours 10a, 10b of the opposite pressing portions 8a, 8b, a receiving area 12 is formed. In the presentation of the Fig. 1a the receiving area 12 is shown open. In other words, the abutting surfaces 14a, 14b of the pressing sections 8a, 8b are spaced apart from each other.

On the outer side surfaces of the pivot elements 4a, 4b, two support elements 16a, 16b are arranged, which are formed in this example in T-shape. By correspondingly provided on the support elements 16a, 16b and on the pivot elements 4a, 4b bores 18a, 18b, the pivot elements 4a, 4b are pivotally connected to the support elements 16a, 16b, for example by means of a bolt. In this way, each swivel element 4a, 4b associated with a rotation axis 20a, 20b. A further bore 18c on each carrier element 16a, 16b is provided for the connection of the carrier element 16a, 16b and thus of the pressing tool 2 with an engine (not shown). The side surfaces of the carrier elements 16a, 16b facing the pivot elements 4a, 4b each have, in this example, a recess 22a, 22b and a countersink 24a, 24b arranged in the recess 22a, 22b. The countersink 24a, 24b may be formed, for example, in the form of a hollow calotte.

The tension mechanism has in the in Fig. 1a shown embodiment, a leg spring 26. In addition, a hollow bolt 28, which in this example is in the form of a hollow cylinder and passes through the turns of the leg spring 26, is provided. At each end face of the bolt 28 is a respective pressure piece 30a, 30b resiliently mounted. An end face of the pressure piece 30a, 30b is pressed against the side surface of the support element 16a, 16b facing the pivot elements 4a, 4b in the region of the recess 22a, 22b and can be guided in a sliding manner, for example via a movement of the bolt 28. In the countersink 24a, 24b, the pressure piece 30a, 30b engage, so that further movement of the bolt 28 is inhibited. The shape of the countersink 24a, 24b is adapted to the shape of the pressure piece 30a, 30b. A change in the orientation of the spring legs 32a, 32b to each other with a spring movement transverse to the spring winding axis 34, in particular along the perpendicular to the connecting line 40 (see Fig. 1b and 1c ) is linked between the two axes of rotation 20a, 20b. Such a spring movement guides the bolt 28 and the pressure pieces 30a, 30b, so that the pressure pieces 30a, 30b are guided along the surface of the recess 22a, 22b. If the end face of the pressure piece 30a, 30b engages in the countersink 24a, 24b, the spring force is insufficient to move the pressure piece 30a, 30b out of the countersink 24a, 24b. The engagement of the end face of the pressure piece 30a, 30b in the countersink 24a, 24b thus corresponds to the second stable state of the tension mechanism in this example.

To the in Fig. 1a To cause the shown voltage mechanism to leave the second stable state, a sliding member 36 is provided as a pulse transformer. An area of the sliding element 36 is adapted to the inner contours 10a, 10b of the pressing sections 8a, 8b. The inner contours 10a, 10b of the pressing sections 8a, 8b have corresponding recesses, so that the sliding element 36 can be integrated flush into the pressing sections 8a, 8b. On the side facing away from the inner contours 10a, 10b of the pressing sections 8a, 8b, the sliding element 36 has two tabs 38a, 38b. The distance between the tabs 38a, 38b is sized so that the leg spring 26 can be interposed therebetween. Accordingly, the pin 28 passes through not only the turns of the leg spring 26 but also the tabs 38a, 38b of the sliding member 36. In this way, the sliding member 36, the leg spring 26, the pin 28 and the plungers 30a, 30b are movably connected together. The recesses 22a, 22b on the support elements 16a, 16b are dimensioned such that the tabs 38a, 38b can be guided flat in them. As a result, in particular, the stability of the arrangement of the sliding element 36 in the direction parallel to the connecting line 40 between the axes of rotation 20a, 20b can be improved.

Fig. 1b shows now in a cross section the in Fig. 1a illustrated pressing tool 2 in a position which corresponds to the second stable state of the tensioning mechanism. The actuating portions 6a, 6b of the pivot elements 4a, 4b abut each other in this example. The abutment surfaces 14a, 14b of the pressing portions 8a, 8b are spaced from each other, the receiving portion 12 is thus open, so that the components to be pressed (not shown) can be introduced.

The bolt 28 is in this second stable state, with respect to the connecting line 40 of the rotation axes 20a, 20b, on the side of the pressing portions 8a, 8b. The guide of the bolt 28 is effected by circular segment-shaped, adapted to the diameter of the bolt 28 recesses 42a, 42b in the mutually facing side surfaces of the pivot elements 4a, 4b, in which from the turns of the leg spring 26, and optionally from the tabs 38a, 38b of the sliding element 36 outstanding areas of the bolt 28 are mounted. Since the bolt 28 is connected to the sliding element 36 via the tabs 38a, 38b, the sliding element 36 protrudes into the receiving area 12.

In this way, a pulse, which causes the voltage mechanism to transition from the second to the first stable state, simply by the introduction of the components to be pressed in the receiving area 12 exercise. A tube, a fitting or a sleeve are pressed during insertion into the receiving area 12 against the contoured, the receiving area 12 facing surface of the sliding element 36 and thereby push it backwards. On the rear side of the sliding element 36, this movement is transmitted to the pin 28 and thus also to the leg spring 26. In particular, the momentum caused by the introduction of the components is sufficient to release the end faces of the pressure pieces 30a, 30b from the countersinks 24a, 24b. However, the pressure pressing pieces 30a, 30b to the support elements 16a, 16b pushing force is then no longer sufficient to further compensate for the force of the leg spring 26, so that by the action of the force of the leg spring 26, the end faces of the plungers 30a, 30b slidably along the Recess 22a, 22b are guided until the first stable state of the tensioning mechanism is reached.

The first stable state of the tension mechanism may be present when the abutment surfaces 14a, 14b of the pressing portions 8a, 8b abut each other, for example, when the receiving portion 12 is free, or when the end faces of the pressure pieces 30a, 30b have reached the end of the recesses 22a, 22b or if the inner contours 10a, 10b bear against the outer peripheral surface of a component located in the receiving region 12. It is also possible in principle for the leg spring 26 to reach its state of relaxation before one of the aforementioned positions has been reached.

The position of the pivot elements 4a, 4b relative to each other in the first stable state of the tension mechanism according to the first of the aforementioned alternatives is exemplified in FIG Fig. 1c shown in cross section. The abutment surfaces 14a, 14b of the pressing portions 8a, 8b abut each other, whereas the operating portions 6a, 6b are spaced from each other. The bolt 28 is in this first stable state with respect to the connecting line 40 of the rotating shafts 20a, 20b on the side of the operating portions 6a, 6b. The circular segment-shaped recesses 42a, 42b are brought together on the side facing the receiving region 12 in such a way that, in cross section, a circle open on one side results, in which the hollow cylindrical pin 28 is arranged. The sliding element 36 is in this example just as far along the perpendicular to the connecting line 40 between the axes of rotation 20a, 20b shifted that its contoured surface is substantially in alignment with the inner contours 10a, 10b of the pressing sections 8a, 8b. In this way, an optimal all-round application of force can be achieved during cold pressing.

Previously, the first stable state has been described so that the abutment surfaces 14a, 14b of the pressing portions 8a, 8b abut each other. This description is based on the fact that no fitting is arranged in the receiving region 12c of the pressing tool 2. If this is the case, however, the first stable state is assumed when the receiving area 12 encloses the fitting contained therein. In this state, the pressing tool 2 can be opened again without causing the fitting to be compressed. If, on the other hand, the pressing tool 2 is completely closed by the motor drive, with the abutment surfaces 14a, 14b being brought into contact with each other, the fitting is compressed. Therefore, the first stable state does not require that the abutment surfaces 14a, 14b abut each other, but that the pressing jaws 4a, 4b are closed by the action of the leg spring 26 until a mechanical resistance has been achieved. This mechanical resistance is different than it is for the second stable state based on Fig. 1b has been described by the engagement of the plungers 32 in the countersinks 24.

Fig. 2a-b show another possible embodiment of the pressing tool 2 according to the invention in an exploded view. The difference to that in the Fig. 1a-c illustrated embodiment is that as a pulse transformer instead of a sliding element 36 two of the pivot elements 4a, 4b subsidiary plates 44a, 44b are provided. However, the principle would work similarly if instead of two sheets 44a, 44b, only one sheet is provided on one side of the pivot members 4a, 4b. The plates 44a, 44b have at one end a bore 46a, 46b, through which the bolt 28 engages. The other end of the plates 44a, 44b protrudes in the in Fig. 2a illustrated second stable state of the tension mechanism in the receiving area 12 inside. Here, too, the components to be pressed, which are brought into the receiving area 12, press against an edge of the sheets 44a, 44b, whereby the bolt 28 and thus the leg spring 26 in the direction of the operating portions 6a, 6b are moved, the end faces the pressure pieces 30a, 30b can be released from the countersink 24a, 24b, and thus the spring spreading mechanism can again act on the actuating portions 6a, 6b. The assignment of in the Fig. 2a-b shown plates 44a, 44b is particularly advantageous when already manufactured pressing tools 2 to be retrofitted with a monostable tensioning mechanism. In this example, only the support plates 16a, 16b and possibly the bolt 28 would have to be exchanged and the plates 44a, 44b added.

Fig. 3a-b show a further possible embodiment of the pressing tool 2 according to the invention in an exploded view. The difference to those in the Fig. 1a-c and 2a-b As illustrated, there are no separate pulse transformers that can cause the voltage mechanism to leave the second stable state and assume the first stable state. Accordingly, the support elements 16a, 16b also have no recesses, which are provided in the previously explained embodiments primarily for guiding the tabs or sheets. Again, the second stable state corresponds to the engagement of the plungers 30a, 30b in the cuts 24a, 24b.

The transition from the second to the first stable state causing pulse can in this embodiment by a further, possibly jerky voltage of Leg spring 26 can be exercised by the operating portions 6a, 6b further merged. By this movement, the leg spring 26 and the pin 28 are further guided in the direction of the pressing portions 6a, 6b, so that the engagement of the pressure pieces 30a, 30b in the counterbores 24a, 24b in the direction of the pressing portions 8a, 8b is released. Due to the then initiated spreading movement of the leg spring 26, the pressure pieces 30a, 30b are again guided in the direction of the actuating portions 6a, 6b along the side surfaces of the support elements 16a, 16b. However, the dynamics of the movement of the plungers 30a, 30b is sufficient to prevent the plungers 30a, 30b from snapping back into the recesses 24a, 24b in the backward movement. Instead, the thrust pieces 30a, 30b, driven by the leg spring 26, slide over the counterbores 24a, 24b, so that the tension mechanism can assume the first stable state.

Fig. 4 shows a possible embodiment of another pressing tool 2 according to the invention in a cross-sectional view. The difference from the preceding embodiments is that the second stable state of the tension mechanism does not correspond to the engagement of thrust pieces 30a, 30b in depressions 24a, 24b arranged on the carrier elements 16a, 16b, but that the second stable state corresponds to the spring dead center position. In this case, the force exerted by the spring legs 32a, 32b on the pivot elements 4a, 4b in the direction of the respective axes of rotation 20a, 20b. In other words, the perpendicular 48a, 48b drawn to the spring leg 32a, 32b at the leg end passes through the pivot axis point 20a, 20b. In this example, the resistance to further movement of the spring legs 32a, 32b formed by the support elements 16a, 16b, which hold the axes of rotation 20a, 20b. A rotational movement can not take place.

If the force direction in the direction of the actuating sections 6a, 6b is now displaced by a further overstretching of the leg spring 26, the rotational movement of the pivot elements 4a, 4b about the axes of rotation 20a, 20b becomes possible again and the transition from the second to the first stable state of the tension mechanism becomes Reason of the dynamics of the relaxation movement initiated. Preferably, the provided on the pivot elements 4a, 4b, from the turns of the leg spring 26 outstanding portions of the bolt 28 leading circular segment-shaped recesses 42a, 42b so dimensioned that the alignment of the spring legs 32a, 32b beyond the Federtotpunktlage addition displacement of the bolt 28 and thus the leg spring 26 in the direction of the pressing sections 8a, 8b is avoided.

Fig. 5 shows a possible embodiment of another pressing tool 2 according to the invention in a cross-sectional view. The difference from the preceding embodiments is that the leg spring 26 has legs 32a, 32b with angled ends. One of the spring legs 32a is arranged in this example in a arranged on one of the pivot elements 4b groove 50, so that this pivot member 4b and the leg spring 26 are firmly connected. The other spring leg 32b, however, can be slidably guided on the side surface of the other pivot member 4a. On this side surface a retaining cam 52 is arranged. The retaining cam 52 is formed so that the angled end of the spring leg 32 b can engage behind. This position of the spring leg 32b corresponds to the second stable state of the tension mechanism, which - as shown - is given in particular when the receiving area 12 is opened, so when the abutment surfaces 14a, 14b of the pressing portions 8a, 8b are spaced. It is basically possible to arrange a plurality of retaining cams 52 one behind the other on a pivoting element 4a, 4b. In this way, several different opening states of the receiving area 12 could be implemented. By engaging behind the spring leg 32 b is prevented from sliding along the side surface of the pivot member 4 a and thus to allow the effect of the force transfer from the spring leg 32 b on the pivot member 4 a compensating or relaxation movement of the leg spring 26. The engaging position of the spring leg 32b can here similar to the in the Fig. 3 and 4 shown embodiments are solved by means of an overvoltage of the leg spring 26. But it is also possible in principle, other features of the preceding embodiments, in particular the pulse transformer, with the in Fig. 5 to be shown combined embodiment.

The present invention is not limited to specific embodiments of the pivotal elements 4a, 4b. For example, the shape of the inner contour 10a, 10b of the pressing sections 8a, 8b can be selected as appropriate for the application. It is also possible to form the press sections 8a, 8b for receiving variable press attachments, which may have differently shaped inner contours 10a, 10b.

In addition, those in the Fig. 1 to 5 shown embodiments of the present invention press tools 2, which for an actuation by means of an engine are provided. However, it is also possible to transfer the features of the present invention to manually operable dies 2 without departing from the scope of the present invention.

Claims (11)

1. Pressing tool (2) for permanently connecting a pipe and a fitting,

   - having two pivoting elements (4a, 4b) which each have an actuating section (6a, 6b) and a pressing section (8a, 8b) and which can be pivoted about a rotational axis (20a, 20b) allocated to them in each case,

   - having two carrier elements (16a, 16b) which are assigned to the pivoting elements (4a, 4b) and which hold the two rotational axes (20a, 20b) and

   - having a bistable clamping mechanism,

   - wherein the inner contours (10a, 10b) of the opposing pressing sections (8a, 8b) of the two pivoting elements (4a, 4b) form a receiving area (12), and wherein

   - the receiving area (12) formed by the inner contours (10a, 10b) is narrower in the first stable state than in the second stable state,
   characterised in that

   - the clamping mechanism has a leg spring (26) arranged between the pivoting elements (4a, 4b), and

   - in that the leg spring (26) is movably mounted with respect to the rotational axes (20a, 20b) of the pivoting elements (4a, 4b),

   - in that the clamping mechanism additionally has a hollow bolt (28) going through the windings of the leg spring (26) and two pressure pieces (30a, 30b) spring-mounted at least partly in the bolt (28), and

   - in that the carrier element (16a, 16b) has an indentation (24a, 24b) matched to a pressure piece (30a, 30b).
2. Pressing tool according to Claim 1, characterised in that the leg spring (26) can move along the perpendicular to a connecting line (40) between the two rotational axes (20a, 20b) of the pivoting elements (4a, 4b).
3. Pressing tool according to Claim 2, characterised in that a certain position along the perpendicular to a connecting line (40) between the two rotational axes (20a, 20b) of the pivoting elements (4a, 4b) corresponds to a certain alignment of the spring legs (32a, 32b) in relation to one another.
4. Pressing tool according to any one of Claims 1 to 3, characterised in that at least one pulse transmitter is provided which is arranged on the inner contours (10a, 10b) of the pressing sections (8a, 8b).
5. Pressing tool according to Claim 4, characterised in that metal plates (44a, 44b) assigned to the pivoting elements (4a, 4b) are provided as pulse transmitters.
6. Pressing tool according to Claim 4, characterised in that a sliding element (36) arranged between the inner contours (10a, 10b) of the pressing sections (8a, 8b) is provided as a pulse transmitter.
7. Pressing tool according to any one of Claims 3 to 6, characterised in that the indentation (24a, 24b) is arranged in a recess(22a, 22b) which is arranged on the carrier element (16a, 16b).
8. Pressing tool (2) for permanently connecting a pipe and a fitting,

   - having two pivoting elements (4a, 4b) which each have an actuating section (6a, 6b) and a pressing section (8a, 8b) and which can be pivoted about a rotational axis (20a, 20b) allocated to them in each case,

   - having two carrier elements (16a, 16b) which are assigned to the pivoting elements (4a, 4b) and which hold the two rotational axes (20a, 20b) and

   - having a bistable clamping mechanism,

   - wherein the inner contours (10a, 10b) of the opposing pressing sections (8a, 8b) of the two pivoting elements (4a, 4b) form a receiving area (12), and wherein

   - the receiving area (12) formed by the inner contours (10a, 10b) is narrower in the first stable state than in the second stable state,
   characterised in that

   - the clamping mechanism has a leg spring (26) with legs (32a, 32b) having angled ends and has at least one retaining lug (52) arranged on at least one of the pivoting elements (4a, 4b).
9. Pressing tool according to Claim 8, characterised in that one of the spring legs (32a) is arranged in a groove (50) which is arranged on one of the pivoting elements (4b).
10. Pressing tool according to Claim 8 or 9, characterised in that a plurality of retaining lugs (52) are arranged one behind the other on the pivoting element (4b).
11. Pressing tool (2) for permanently connecting a pipe and a fitting,

    - having two pivoting elements (4a, 4b) which each have an actuating section (6a, 6b) and a pressing section (8a, 8b) and which can be pivoted about a rotational axis (20a, 20b) allocated to them in each case,

    - having two carrier elements (16a, 16b) which are assigned to the pivoting elements (4a, 4b) and which hold the two rotational axes (20a, 20b) and

    - having a bistable clamping mechanism,

    - wherein the inner contours (10a, 10b) of the opposing pressing sections (8a, 8b) of the two pivoting elements (4a, 4b) form a receiving area (12), and wherein

    - the receiving area (12) formed by the inner contours (10a, 10b) is narrower in the first stable state than in the second stable state,
    characterised in that

    - the clamping mechanism has a leg spring (26) arranged between the pivoting elements (4a, 4b),

    - in that the leg spring (26) is movably mounted with respect to the rotational axes (20a, 20b) of the pivoting elements (4a, 4b) and

    - in that the second stable state corresponds to the dead centre position of the spring.

Images