EP1519813A2 - Electrohydraulic pressing device and method for operating the same - Google Patents

Abstract

The invention relates to an electrohydraulic pressing device ( 1 ) that can be operated using one hand. The device comprises a working head ( 30 ), an electric motor ( 4 ), a pump ( 20 ), a hydraulic reservoir ( 33 ), and a gear mechanism ( 19 ) extending between the electric motor ( 4 ) and the pump ( 20 ). A holding area ( 5 ) around which a hand is placed is provided and an actuating switch ( 39 ) is assigned to this area. The aim of the invention is to improve a pressing device of this type with regard to the handling thereof. To this end, the invention provides that the holding area ( 5 ) is formed around the electric motor ( 4 ), and the actuating switch ( 39 ) is situated between the electric motor ( 4 ) and the working head.

Description

Electro-hydraulic nerpress device and method for operating the same

The invention relates first of all to an electro-hydraulic nerpress device suitable for one-hand operation with a working head, an electric motor, a pump, a hydraulic tank and a gearbox between the electric motor and the pump, a handle area which is to be encompassed by one hand and to which an actuation switch is assigned ,

In addition to the usual two-hand operated electrohydraulic pressing devices, lighter embodiments for one-hand operation are known. These are used for the pressing of, for example, pipe connections or the pressing of cable lugs at the ends of the electrical cables, a lower pressing force, for example of 31, being achieved in these one-hand pressing devices in comparison with the known heavier two-hand pressing devices.

In view of the prior art described above, a technical problem of the invention is seen in designing a nerpress device of the type in question with improved handling.

This problem is solved first and for the most part by the subject matter of claim 1, with the focus being on the grip area being embodied comprehensively with the electric motor and the actuation switch being arranged on the working head side of the electric motor. As a result of this configuration, there is an improvement in the handling of a pressing device in question. The arrangement of the grip area according to the invention allows a substantially rod-shaped configuration of the pressing device, with which it can be held ergonomically as a tool with one hand can. The actuation switch is furthermore arranged in an ergonomically favorable manner on the working head side of the electric motor and is therefore preferably index finger or thumb actuated. In addition, it proves to be favorable in terms of handling that a central axis of the grip area overlaps the central axis of the electric motor or parallel to it, offset in the direction of the working head of the pressing device.

The invention further relates to a pressing device according to the features of the preamble of claim 1, it being proposed here for the handling-related improvement of such a pressing device that the grip area is formed in the center of gravity of the device and opposite the device, assigned to an index finger / thumb placement the operating switch and an emergency switch is designed. As a result of this configuration according to the invention, there is an improved handling of the pressing device, this inventive solution being important both individually and in conjunction with the characterizing part of claim 1. For example, the handle area is ergonomically favorable in the center of gravity of the device, which focus is, for example, in the case of a rod-shaped configuration of the pressing device in the area of the electric motor. The arrangement of the actuation switch and the emergency switch to interrupt the pressing operation has proven to be particularly advantageous. Both switches can be actuated by the hand encompassing the grip area, with the switch being arranged opposite one another, preferably the actuating switch, being able to be operated by the index finger and the opposite emergency switch preferably being thumb-actuated. As a result, the user can quickly respond to an emergency situation by using the thumb.

The following inventive features are further developments and the invention according to claim 1 and that according to claim 2 and above In addition, a combination of claims 1 and 2. Accordingly, an electrohydraulic pressing device can be provided which, for one-hand operation, forms a grip area comprising the electric motor, the actuating switch being arranged on the working head side of the electric motor and the grip area being formed in the center of gravity of the device, above it opposite the device, assigned to an index finger / thumb placement, the actuation switch and an emergency switch is formed. In this regard, it proves to be particularly advantageous if the actuating switch is arranged one to four fingers wide from an end face of the electric motor. Accordingly, the actuation switch is easily accessible without having to move the hand carrying the device from its original place. In order to prevent the pressing device from rolling off when the pressing device is essentially rod-shaped, it is further proposed that the device be widened on one side opposite the working head. As a result of this configuration, a rolling obstacle is formed on the housing side. It proves to be particularly advantageous here that the widening is partly formed by an accumulator and, in addition, partly by the housing-side receiving area for the accumulator. It is further proposed that the widening is formed cantilevered to the side on which the actuation switch is formed, with which the widening protects the actuation switch against inadvertent actuation when the device is put down. The extent to which the widening extends beyond the cross-sectional configuration of the housing, which is rod-shaped in particular in the handle area, corresponds to approximately one to two thirds of the handle area diameter. A further major advantage is that the central axis of the electric motor is aligned with the axis of a pump tappet. As a result, the desired configuration, which is almost rod-shaped over the entire longitudinal extent of the pressing device, is achieved, furthermore that between the electric motor and the pump arranged gear with its central axis is also aligned with the axis of the pump tappet and the electric motor. Accordingly, the electric motor, gearbox and pump are provided in an axial arrangement one behind the other. In a further development of the subject matter of the invention, a return valve is arranged in a side-by-side arrangement with the pump tappet, which opens after the maximum pressing force has been reached and causes the hydraulic oil to flow back into the hydraulic tank. The return valve is preferably evident manually if necessary via the emergency switch, this emergency switch also acting mechanically on the return valve. It proves to be particularly advantageous here that surrounding the pump tappet and / or the

Return valve a hydraulic tank is arranged approximately in a ring, whereby short flow paths for the hydraulic oil are achieved. In order to further specify the generally rod-shaped configuration of the pressing device, it is provided that the accumulator can be plugged in the axial direction of the electric motor, a central axis of an accumulator plug-in projection or a central axis of the housing-side receptacle being aligned with the central axis of the electric motor. In this regard, it has also proven to be particularly advantageous that a central axis of the working head receptacle is aligned with a central axis of the electric motor. Accordingly, in a preferred embodiment of the pressing device, the central axis of the working head receptacle, the axis of the pump plunger in the area of the pump, a central axis of the transmission and the central axis of the electric motor and the central axis of the battery plug-in projection are aligned with one another, so that this linear arrangement of the an essentially rod-shaped, ergonomically favorable configuration of the pressing device that supports the one-hand operation is achieved for individual assemblies.

The invention further relates to an electrohydraulic pressing device with a working head, an electric motor, a pump, and a hydraulic tank and a gearbox between the electric motor and the pump, wherein a grip area, which is to be encompassed by a hand and to which an actuation switch is assigned, is provided with a working piston for actuating a pressing tool. When crimping cable end sleeves or pipe fittings, it often proves problematic that they move out of the desired crimping position in the course of crimping using the crimping device. Such a compression can then be unusable. In order to counteract this disadvantage, it is proposed according to the invention that the working piston can first be moved into a stop position when the device is actuated and then, if necessary time-controlled, can be moved into the pressing position. In this stop position, the workpiece, e.g. the cable lug is held in the pressing tool in such a way that the workpiece can still be easily moved into the desired pressing position. Only then is the working piston moved into the pressing position to actuate the pressing tool. In the holding position, the force acting on the workpiece is considerably less than the maximum pressing force, so that the workpiece is held securely in the pressing tool without the same being deformed. As mentioned, the process into the pressing position can be delayed. However, an embodiment is preferred in which the method into the pressing position can be triggered by actuating the actuation switch again. Electronic control is also conceivable, in which, for example, a pulse width control of the electric motor controls the movement of the working piston. Thus, it can be provided that the electric motor only exerts a very small force in a first step, that is to say it switches itself off when the stop position is reached. After pressing the actuation switch again, the actual pressing is carried out. Furthermore, it is possible to overrun the intermediate position of the pressing tool, that is to say the holding position thereof, by continuously actuating the actuation switch. A further development of the subject matter of the invention provides that the Working piston is designed divided and that after starting against a workpiece, the sections of the working piston first move against each other. In this regard, it is further preferred that the partial sections of the working piston are biased into an extended position by a spring. It can further be provided that the partial sections of the working piston interlock in a telescopic manner. The stop position is clearly defined here by moving the prestressed sections of the working piston against each other. The force of the spring that biases the partial sections apart is dimensioned in such a way that no force that causes a deformation of the workpiece can be applied to the workpiece. The increase in the counterforce on the working piston caused by this spring can also be detected electronically. In addition, a sudden, electronically detectable switch-off point can also be measured as a result of the sudden increase in the counterforce when the partial sections move against one another in the holding position. In addition, there is the possibility of detecting the approaching of the sections by means of a sensor system, which causes the electric motor to be switched off. After reaching the stop position, as stated, the final movement of the working piston into the pressing position is carried out by pressing the actuation switch again, whereby the working piston is displaced against a further return spring.

The invention also relates to a method for operating an electrohydraulic pressing device with a working head, an electric motor, a pump, a hydraulic tank and a transmission between the electric motor and the pump, wherein a handle area that is to be encompassed by a hand and to which an actuation switch is assigned is provided. with a working piston for actuating a pressing tool. In order to provide an improved method of the type in question with regard to the handling of the device, it is proposed that the working piston is first moved into a stop position and before the process is held in the pressing position, the holding position in which the force acting on the workpiece is substantially less than the maximum pressing force. As a result of this configuration, before the workpiece is finally pressed, it can still be moved into the desired pressing position in the held position. The force acting on the workpiece is such that the workpiece is held securely in the press tool. The force does not have a deforming effect on the workpiece. With a pressing force of 3 1, for example, a holding force can be selected which corresponds to approximately one hundredth to one tenth of the pressing force. The process in the pressing position can be time-controlled offset.

However, a solution is preferred in which the method into the pressing position is triggered by actuating the actuation switch again. So this process in the pressing position is only possible with an emphasis on the will. In order to enable a workpiece to be pressed in the holding position even without an intermediate stop, the working piston can be moved continuously from the basic position to the pressing position by holding the actuation switch. However, a solution is preferred in which the pressing process is manually interrupted after reaching the stop position. This means that the operation of the working piston is started by actuating the actuation switch once. Only a manual interruption of the working piston process causes the stop in the stop position. It is preferred here that the manual interruption is carried out by actuating the actuation switch, which in particular in connection with an electric motor with a short-circuit brake causes the working piston advance to be interrupted immediately. In this regard, it is also conceivable that an electronically controlled interruption of the pressing process takes place after the stop position has been reached. For example, pulse width control of the electric motor can be provided. In addition, a method is also conceivable in which a sensor system detects the position of the working piston or one Part of the working piston is detected and in the stop position causes the electric motor to be switched off.

The invention is explained in more detail below with reference to the accompanying drawings, which only show several exemplary embodiments. It shows:

1 a perspective view of an electrohydraulic pressing device suitable for one-hand operation, with a pressing tool of a first embodiment;

2 shows the longitudinal section through the pressing device and the pressing tool;

3 shows the section along the line III-III in Fig. 2.

FIG. 4 shows an enlargement of the area on the working head side from FIG. 2; FIG.

5 shows an enlargement of the aforementioned area from FIG. 3;

FIG. 6 shows an explosion perspective view of the pressing device according to FIG. 1;

7 shows a partially sectioned illustration of the pressing tool of the first embodiment in the unloaded basic position;

8 shows a representation corresponding to FIG. 7, but relating to the stop position; FIG. 9 shows another representation of the pressing tool corresponding to FIG. 7, but in the pressing position;

10 shows a perspective view of the pressing device corresponding to FIG. 1 with a pressing tool in a second embodiment;

11 shows a representation corresponding to FIG. 4, but relating to the pressing tool according to FIG. 10;

12 shows a partially sectioned individual illustration of the pressing tool of the second embodiment in the unloaded basic position;

13 shows a representation corresponding to FIG. 12, relating to the holding position;

FIG. 14 shows another representation corresponding to FIG. 12, but relating to the pressing position;

15 shows a perspective illustration of the pressing device corresponding to FIG. 1 with a pressing tool in a third embodiment;

16 shows a sectional illustration corresponding to FIG. 4, but relating to the pressing device with a pressing tool according to FIG. 15.

Shown and described is first of all with reference to FIG. 1 an electrohydraulic pressing device 1 suitable for one-hand operation for actuating and Different pressing tools 2. The latter are used for pressing pipe fittings, cable lugs or the like.

As can be seen from the illustrations, the pressing device 1 is essentially elongated and rod-shaped, which supports the one-hand operation of the device. This rod-shaped configuration is achieved in that the individual assemblies are positioned in the housing 3 of the device 1 in an axial arrangement one behind the other. For example, an electric motor 4 is provided in the central region, the central axis y of which is aligned with the housing axis x. In the area of the electric motor 4, the housing 3 forms a grip area 5, the housing diameter in this grip area 5 being selected to be ergonomically adapted.

The electric motor 4 is fed by an accumulator 6 which can be plugged in in the axial direction of the electric motor 4. The central axis u of the accumulator plug-in projection 8 which can be inserted into a corresponding housing receptacle 7 is positioned on the housing axis x in alignment with the electric motor axis y.

The inserted rechargeable battery 6 is locked in place, for which purpose a latching projection 10 fastened to a resilient arm 9, penetrating a correspondingly positioned opening of the rechargeable battery holder 7, engages in a latching recess 11 of the plug-in projection 8.

This locking device can be canceled by means of a rocker-like locking button 13 which can be displaced about an axle body 12 oriented transversely to the longitudinal extent of the pressing device 1. By depressing this locking button 13, the locking projection 10 is pivoted out of the locking receptacle 11, after which the battery 6 can be removed. The electrical contacting of the accumulator 6 is not shown. Between the latter and the electric motor 4, a circuit board 14 is interposed both electrically and, based on the arrangement within the housing 3, which carries a switch 15 and, if appropriate, further electronic assemblies.

By means of the electric motor 4, a working piston 16 is moved in a known manner in the pressing device 1 by increasing the oil pressure against the force of a piston return spring 17, for displacing a movable jaw of the pressing tool 2. Working piston 16 and piston return spring 17 are part of the pressing tool 2.

In order to implement the linear displacement of the working piston 16 under oil pressure from the rotational movement of the motor shaft 18 aligned on the central axis y of the electric motor 4, a gear 19 is arranged between the electric motor 4 and a pump 20. The gear 19 is a roller gear, as is known from the applicant's unpublished German patent application 101 24267.0. The content of this patent application is hereby incorporated in full into the disclosure of the present invention, also for the purpose of including features of this patent application in claims of the present invention.

The transmission 19 converts the rotational movement of the motor shaft 18 driven by the electric motor 4 into an oscillating pump movement of a pump tappet 21. This reciprocating pump movement takes place in the axial direction of the motor shaft 18, both the central axis v of the transmission and the central axis z of the pump plunger 21 being aligned with the central axis y of the electric motor 5 on the device axis x. The gearbox 19 is composed essentially of a lower raceway body 23 arranged in a circular cylindrical casing 22, an upper raceway body 24 and two output rotation bodies 26 arranged between the raceway bodies 23 and 24 and held in a cage 25.

The raceway bodies 23 and 24, coaxially aligned with the motor shaft 18 of the electric motor 4, are held in the casing 22 in a rotationally fixed manner. Each track body 23, 24 has tracks 27, 28 which face one another.

Between the lower raceway body 23 facing the electric motor 4 and the upper raceway body 24 facing away from the electric motor 4, the output rotation bodies 26 are arranged, which are disc-shaped, the axes of rotation of these output rotation bodies 26 being aligned parallel to the central axis y of the Electric motor 4 or to the central axis v of the transmission 19.

The output rotating bodies 26 interact on both sides with their peripheral edges with the respectively assigned raceways 27, 28 of the raceway bodies 23, 24.

The output rotation body 26 are held in a cage 25 such that they are diametrically opposite with respect to the motor shaft 18. The motor shaft 18 passes through the bottom of the lower raceway body 23 and in the center of the cage 25, a motor shaft end projecting beyond the rear of the cage 25. The rotating bodies 26 each have a shaft engagement surface formed by the circumferential circumferential surface. These, like the surface of the motor shaft 18, have a smooth surface, after which the interaction of the motor shaft 18 and the rotating bodies 26 takes place in a frictional manner.

The raceways 27, 28 of the two raceway bodies 23, 24 are inclined toward the motor shaft 18, the raceway 27 of the lower raceway body 23 viewed in cross section with the central axis y of the electric motor 4 toward the motor-side end of the motor shaft 18 viewed at an acute angle and the raceway 28 of the upper raceway body 24, also in cross section with the central axis y of the electric motor 4 towards the free end of the motor shaft 18, also includes an acute angle. These acute angles are approximately 45 °.

As a result of this configuration of the raceways 27, 28, conical surfaces are shaped, with which the peripheral edge edges of the rotating bodies 26 interact. The upper raceway body 24 is furthermore held in the jacket housing 22 so as to be displaceable in the axial direction, wherein this is biased in the direction of the output rotation body 26. This preload is achieved by a compression spring 29 acting on the pump tappet 21, which is supported on the upper raceway body 24 on the side facing away from the rotary body.

Due to this prestressing of the upper raceway body 24, the rotating bodies 26 are always acted upon axially inwards, so that the frictional connection between them and the motor shaft 18 is ensured.

The raceway 27 of the lower raceway body 23 is milled out of the raceway body 23 according to a circular shape in accordance with a floor plan. Zufol- ge of which the raceway engagement surfaces of the rotating bodies 26 interact with a circular orbit of the lower raceway 27. The raceway 28 of the upper raceway body 24, on the other hand, is produced, for example, by means of a milling cutter deviating from a circular shape, so that an elliptical outline of the upper raceway 28 results, with a constant cone angle to the motor shaft 18. As a result, the raceway 28 of the upper raceway body 24 in terms of the height of the rotating bodies 26, with the rotating bodies 26 rotating on a circular path, from the perspective of the rotating bodies 26. As a result of the previously described raceway configurations, the prestressing results in a height adjustment of the upper raceway body 24 by axially displacing the latter in the course of the rotation of the rotary bodies 26 driven by the motor shaft 18.

The constant rotation of the rotary bodies 26 accordingly causes an oscillating movement of the upper raceway body 24 and, moreover, of the pump plunger 21, which is spring-loaded on the upper raceway body 24. Accordingly, the raceway body 24 to be assigned to the gear 19 simultaneously forms part of the pump 20.

By means of this oscillating movement of the pump tappet 21, the already mentioned working piston 16 is pressurized with oil via a valve arrangement, not shown in any more detail. The working piston 16 lies here in a cylindrical receptacle of a working head 30 on the pressing device, the central axis w of the hollow cylindrical one being provided with an external thread

Working head 30 is aligned with the central axis y of the electric motor 4 and thus also aligned with the other assemblies and the main device axis x. Furthermore, in a side-by-side arrangement, ie offset parallel to the pump tappet 21, a return valve 31 is provided, which is connected at one end to the pressure chamber 32 in front of the working piston 16. This return valve 31 opens automatically when a predefined pressure in the pressure chamber 32 is exceeded and opens a path to the hydraulic tank 33 which surrounds the pump 20 or the pump tappet 21 and the return valve 31 in a ring shape. This hydraulic tank 33 is accordingly in the immediate vicinity of the pump 20 the side of the transmission 19 facing away from the electric motor 4.

Opening the check valve 31 causes the piston 16 to return the working piston 16 to the unloaded basic position.

In addition, the return valve 31 can also be triggered manually. For this purpose, an emergency switch 34 designed as a reset slide is provided in the device housing 3 in the immediate vicinity of the return valve 31, which, when actuated by a slide 35, displaces the valve tappet 36 against the force of a compression spring 37 which presses the tappet 36 into the blocking position.

To switch on the electric motor 4, an actuating switch 39 is provided on the side of the device housing 3 opposite the emergency switch 34, which can be pivoted about an axis body 38 oriented transversely to the housing axis x and which can be finger-operated against the force of a compression spring 40 supported on the casing 22 of the transmission 19 indented. The button-like actuation switch 39 is arranged on the working head side of the electric motor 4 in the area of the transmission 19 and acts on the switch 15 arranged on the circuit board 40 via a shift lever 41 which leads past the electric motor 4. As already indicated, the pressing device 1 is essentially rod-shaped in an elongated manner. The grip area 5 comprising the electric motor 4 is formed in the center of gravity of the device 1 and extends approximately from the end of the electric motor 4 on the working head side, essentially in the shape of a cylinder, into the area of the battery holder 7 into a one-sided widening 42, which widening 42 is also partially formed by the accumulator 6. This widening 42 protrudes to the side on which the operating switch 39 is formed. As a result of this configuration, an obstacle to rolling is created.

A radially circumferential extension zone 43, essentially comprising the hydraulic tank 33, is also provided towards the end on the working head side, with the result that the actuating hand that grips the grip area 5 slides forward in the direction of the working area.

Furthermore, the actuation switch 39 is placed in such a way that it is arranged approximately one to four fingers away from the end of the electric motor 4 on the working head side and is therefore easily accessible by the index finger of the actuating hand. In addition, the opposite emergency switch 34 can be detected by the thumb of the same hand.

Conventional pressing tools 2 can be actuated by means of the pressing device 1 described above. 1 to 9, a first embodiment of such a pressing tool 2 is shown. This is a C-shaped pressing tool with a sliding jaw 44 which can be displaced linearly by the working piston 16 and an opposing fixed jaw 45. Both jaws 44 and 45 carry press inserts 46, for example, for crimping a cable lug 47 onto a cable end 48.

The working piston 16 is designed in two parts in such a way that a first section 50 provided with an piston head 49 that can be pressurized with oil pressure telescopically engages in a hollow section second section 51, the sections 50 and 51 being inserted into the second section 51 and against the first section 50 supporting compression spring 52 are biased into an extended position.

This prestressed position is limited by the screw head of a screw 53, which penetrates the first section 50 and the compression spring 52 centrally and is screwed into the bottom section of the second section 51 (cf. FIG. 7).

The piston head 49 is enlarged in cross-section compared to the second partial section 51 that overlaps the first partial section 50 and, in a conventional manner, carries an annular seal 54 for sealing the pressure chamber 32 in a radially circumferential groove.

Furthermore, the piston head 49 together with the associated first partial section 50 is supported via the piston return spring 17 against the bottom of the counter receptacle 55 which is formed on the pressing tool side and surrounds the working piston 16 and is provided with an internal thread.

The second section 51 of the working piston 16 penetrates the bottom of the counter receptacle 55 with its solid end opposite the piston head 49 and is connected to the sliding jaw 44, so that linear publishers stanchions of the second section 51 are transferred to the sliding jaw 44.

The division of the working piston 16 into two proves to be advantageous in that the movable jaw — here the sliding jaw 44 — of the pressing tool 2 can initially be moved into a holding position as shown in FIG. 8 and can be held there in the pressing position before another method , The pressing device 1 is switched on by actuating the actuation switch 39, whereupon the electric motor 4 increases the oil pressure in the pressure chamber 32 via the gear 19, which results in a linear displacement of the working piston 16 and, via this, the sliding jaw 44. The two sections 50 and 51 initially remain in their extended positions due to the compression spring 52 provided. As soon as the workpiece to be pressed - here the cable lug 47 - is clamped between the press inserts 46, this leads to a telescopic movement of the two sections 50 and 51 against the force of the compression spring 52 until these sections move against each other. This means that with increasing oil pressure over the distance between the free end region 56 of the second section 51 and the opposite end face 57 of the first section 50 there is no displacement of the sliding jaw 44.

This situation can be recorded electronically, which electronics cause the electric motor to be switched off, so that the user can still move the clamped workpiece between the press inserts 46. It is preferred, however, that in this stop position, as shown in FIG. 8, the pressing process is manually interrupted by actuating the actuation switch again. If this stop position is not desired, the user can refrain from actuating the actuation switch 39 again, whereupon the pressing process is carried out continuously without an intermediate stop. 8, the pressing process can be continued by pressing the actuation switch 39 again, whereby after the end region 56 of the second section 51 has moved against one another, the working piston 16 counteracts the end face 57 of the first section 50 the force of the piston return spring 17 is shifted further into the pressing position according to FIG. 9.

When a certain pressing force is exceeded, the return valve 31 of the pressing device 1 opens automatically, whereupon the working piston 16, supported by the piston return spring 17, is moved back into the basic position and the sections 50 and 51 are also brought into their spaced position by the action of the compression spring 52 be shifted towards each other.

11 to 14, a pressing tool 2 is shown in a second embodiment. This pressing tool 2 can also be arranged on a pressing device 1 as described above.

According to the exemplary embodiment described above, two partial sections 50, 51 are also provided for forming the working piston 16 in this pressing tool 2, which partial sections 50, 51 engage telescopically and are prestressed into an extended position by means of a compression spring 52.

The pressing tool 2 is shaped like a beak head with a fixed jaw 45 carrying a pressing insert 46 and a pivotably mounted swiveling jaw 58, which likewise carries a pressing insert 46. This pivot jaw 58 is connected to the working piston 16 or its second part. Cut 51 connected and acting on the leg of the pivoting jaw 58 lever 59 from a basic position according to FIG. 12 to a pressing position according to FIG. 14, whereby a holding position is also provided according to the representation in FIG. 13, in which the workpiece to be clamped - here, too, a cable lug 47 is clamped between the press inserts 46. In accordance with the embodiment described above, this is achieved by telescoping the two sections 50 and 51 of the working piston 16. Only after the end face 57 of the first section 50 has struck against the end region 56 of the second section 51 is preferred, by actuating the actuation switch 39 again - The further displacement of the pivot jaw 58 in the pressing position shown in FIG. 14 can be reached.

15 and 16 show a further embodiment of a pressing tool 2 which, contrary to the previously described exemplary embodiments, is provided with a one-piece working piston 16. As a result, no stop position is provided for this pressing tool 2. By increasing the oil pressure, the working piston 16 is continuously shifted from the basic position to the pressing position counter to the piston return spring 17.

In this pressing tool 2, too, a linearly displaceable sliding jaw 44 connected to the working piston 16 is provided with a pressing insert 46, which is displaced against a fixed jaw 45 with pressing insert 46. To attach the pressing tool 2 to the workpiece to be pressed, the fixed jaw 45 can first be pivoted about an axis 60. After attachment, the L-shaped leg of the fixed jaw 45, which can be pivoted about the axis 60, is pivoted back into its working position and is held by means of a locking lever 62 which can be pivoted about a further axis 61 arranged opposite the axis 60. All of the features disclosed are (in themselves) essential to the invention. The disclosure content of the associated / attached priority documents (copy of the prior application) is hereby also included in full in the disclosure of the application, also for the purpose of including features of these documents in claims of the present application.

Claims

EXPECTATIONS

1. Suitable for one-hand operation electrohydraulic pressing device (1) with a working head (30), an electric motor (4), a pump (20), a hydraulic tank (33) and a gear (19) between the electric motor (4) and the pump ( 20), wherein a handle area (5) that is to be encompassed by a hand and to which an actuation switch (39) is assigned, characterized in that the handle area (5) is designed to be comprehensive with the electric motor (4) and the actuation switch (39) is arranged on the working head side of the electric motor (4).

2. pressing device according to the features of the preamble of claim 1, characterized in that the grip area (5) is formed in the center of gravity of the device (1) and opposite to the device (1), assigned an index finger / thumb placement of the actuation switch (39) and an emergency switch (34) is formed.

3. pressing device according to one or more of the preceding claims or in particular according thereto, characterized in that the actuating switch (39) is arranged one to four fingers wide away from an end face of the electric motor (4).

4. A pressing device according to one or more of the preceding claims or in particular according thereto, characterized in that a widening (42) on one side of the working head (30) is located opposite the working head (30)

Device (1) is formed.

5. pressing device according to one or more of the preceding claims or in particular according thereto, characterized in that the widening (42) is partially formed by an accumulator (6).

6. pressing device according to one or more of the preceding claims or in particular according thereto, characterized in that the widening (42) is formed projecting to the side on which the actuating switch (39) is formed.

7. pressing device according to one or more of the preceding claims or in particular according thereto, characterized in that the central axis (y) of the electric motor (4) is aligned with the axis (z) of a pump tappet (21).

8. pressing device according to one or more of the preceding claims or in particular according thereto, characterized in that a return valve (31) is arranged in a juxtaposition to the pump tappet (21).

9. pressing device according to one or more of the preceding claims or in particular according thereto, characterized in that a hydraulic tank (33) is arranged surrounding the pump tappet (21) and / or the return valve (31).

10. pressing device according to one or more of the preceding claims or in particular according thereto, characterized in that the accumulator (6) in the axial direction of the electric motor (4) can be plugged.

11. pressing device according to one or more of the preceding claims or in particular according thereto, characterized in that a central axis se (w) of the working head receptacle is aligned with a central axis (y) of the electric motor (4).

12. Electro-hydraulic pressing device (1) with a working head (30), an electric motor (4), a pump (20), a hydraulic tank (33) and a gear (19) between the electric motor (4) and the pump (20), A handle area (5), which is to be encompassed by one hand and to which an actuation switch (39) is assigned, is provided with a working piston (16) for actuating a pressing tool (2), characterized in that the working piston (16) when actuated of the device (1) can first be moved into a stop position and then can be moved into the pressing position.

13. pressing device according to claim 12 or in particular according thereto, characterized in that the method in the pressing position can be triggered by pressing the actuation switch (39) again.

14. Pressing device according to one or more of claims 12 to 13 or in particular according thereto, characterized in that the working piston (16) is of split design and that after starting against a workpiece, first the partial sections (50, 51) of the working piston (16) move against one another.

15. Pressing device according to one or more of claims 12 to 14 or in particular according thereto, characterized in that the sections (50, 51) of the working piston (16) are biased by a spring (52) into an extended position.

16. Pressing device according to one or more of claims 12 to 15 or in particular according thereto, characterized in that the partial sections (50, 51) of the working piston (16) intermesh telescopically.

17. Method for operating an electrohydraulic pressing device (1) with a working head (30), an electric motor (4), a pump (20), a hydraulic tank (33) and a transmission (19) between the electric motor (4) and the pump (20), with a grip area encompassing one hand

(5) is provided, to which an actuating switch (39) is assigned, with a working piston (16) for actuating a pressing tool (2), characterized in that the working piston (16) is first moved into a holding position and before moving into the pressing position is held there in which holding position the force acting on the workpiece is significantly less than the maximum pressing force.

18. The method according to claim 17 or in particular according thereto, characterized in that the method is triggered into the pressing position by actuating the actuating switch (39) again.

19. The method according to one or more of claims 17 to 18 or in particular according thereto, characterized in that the pressing process is interrupted manually after reaching the stop position.

20. The method according to one or more of claims 17 to 19 or in particular according thereto, characterized in that the manual interruption is carried out by actuating the actuation switch (39).

21. The method according to one or more of claims 17 to 20 or in particular according thereto, characterized in that an electronically controlled interruption of the pressing process takes place after reaching the stop position.