EP1112149B1 - One-hand actuated, self-closing pliers - Google Patents

Description

The invention relates to a one-hand operated, self-adjusting pliers according to the features of the preamble of claim 1.

In the case of known pliers of this type, compare EP 0 854 011 A1, there is a Control is provided in the form of a toggle lever, which by a partial on the movable pliers leg and partly on a knee lever element supported spring is biased into an extended position. Only after investment in the The stretched position is canceled and a workpiece Bend the knee lever towards the pliers mouth. However A separate spring is provided to open the jaws of the pliers. This does the known pliers are relatively complex.

Proceeding from this, the invention deals with the task of one self-tongs in a simple advantageous embodiment specify.

This object is achieved with the subject matter of claim 1. The spring drive consists of a spring supported on both pliers legs, so is designed that both a The jaws are spaced apart, as well as a method of moving the pliers leg in the largest mouth opening position, while rotating the Pliers leg is caused by this spring, being at least on one side a rotating support of the spring is formed on the pliers leg and the spring this side in the actuated state against one on the Pliers limb trained rotary stop, when moving the movable pliers leg in a jaw closing position that grips a workpiece Spring only after power is applied when the jaws of the pliers are in contact on the workpiece from the rotary stop comes. This results in a self-contained power system, integrated into a control. The feather is so biased that the movable pliers leg with the pliers released into the open position fast. The control is supported by a pair of pliers legs Spring is formed, which at the same time the pliers mouth preloads the open position. The rotation stop is designed as a supporting flank. This can be done technically easy to take into account. Provided at one Leg spring are two spring sections, that are differently rigid. That yields a working order of the spring drive. Brings further the invention in proposal that the different Rigidity due to a different length of the spring sections is achieved. It is also provided that the Spring into the two spring sections by means of one Spring winding is divided. Such a multi-layer executable spring turn contains a customized stored Spring force reserve. It is also provided that the spring articulation points differently close to that Pliers mouth are arranged. Specifically, it looks like that the pivot point of the longer spring section closer is on the pliers mouth.

The shorter spring section is supported against the pliers mouth not exceedable. Provisions have been made that a Rotational mobility of the short spring section in the Articulation point is limited in angle. It is intended here that the angle of rotation is an acute angle. Is further provided that the spring two turns side by side having. This results in an even more balanced one Force system, especially a good spring characteristic.

The rigid section is like the short section of spring, going against the pliers mouth supported not exceedable. It is still proposed that the spring section is formed by a spiral spring. It can be here even dealing with a leaf spring with a central one non-circular cross-section of slip-free end turn. It is advantageous that the rigid section is a handlebar, at one end the spring element is attached in the manner described and its other end rotatably arranged on the pliers leg is, again here with the proviso that it cannot be exceeded Support.

Stabilizing it is advantageous if the handlebar is formed in pairs and by spacing the two Handlebars a space for the spring and the spring attachment leaves. It is advantageous that the Spring attachment by a winding package Passing spring turn, connecting the handlebars Trunnion is achieved. The spring is tied up so securely. It is also favorable that the rigid section facing spring section as a torsion spring trained spring itself on the rigid section supported. The support can be cut free Tongue of the handlebar; alternatively can the support of one that also connects the handlebars Be formed cones. Then in proposal brought that spring to two knee-like together connected rigid sections is supported. to Support of the spring tension can continue like this be proceeded that one of the rigid sections through a second spring arranged on the handle section in With regard to an extended position of the rigid sections is biased towards each other. Regarding the above Stretch position is to be said that the two rigid sections in the stretched state between you Include an opening angle of less than 180 ° on the mouth side. So a dead center is like a knee interconnected rigid sections between the Articulation points of the pliers legs prevented. further one characteristic is that the other Spring-connected rigid section is double-armed. The Spring action is so in the same direction as the other, first Feather.

A pair of pliers with a minimum of components is achieved if the spring as a bow spring with bow arms and a bracket turn is formed, the bracket arms on one of the pliers legs and the stirrups another of the pliers legs is supported. spring and Control elements are designed integrally. The bow arms or the stirrups are one on one Pliers legs supported on a rotatably mounted rigid section. The spring preload of the spring drive as well the spring force itself is thereby applied that the cantilever arms on a rigid section or a pliers leg over different axes of rotation are rotatably supported. The distance between the axes of rotation is aimed at pivoting the pliers legs Implemented spring force. The bow arms are different long trained. That in association with the spaced axes of rotation leads to a torsional effect in the loop and also to a certain degree of curvature the bow arms. The bow arms can be curved Show course, for example in the sense of an already easy Precurvature. The curvature faces the forceps mouth concave. It is also proposed that on the rigid section when the Spring drive stop cooperating with the spring is trained. It can also be advantageous that the loop turn is helical. About here can also achieve a bearing eye. The bearing eye is not claimed in the sense of a torsion effect. In addition, it is provided that the loop turn on a pliers leg is supported for longitudinal movement. A simple assignment is achieved in that the stirrups in an elongated hole in a pair of pliers is included. To close the order of the mouth and power grip of the same with simple means To be able to comply, it is proposed that the support the stirrup is profiled with one inclined to the longitudinal direction of the pliers leg and the initial support surface that traps the bend. An alternative feature is that at the Stirrups a one acting in the longitudinal direction of the pliers legs Tension spring attacks.

Fig. 1

die Zange in Seitenansicht in federbelasteter Grundstellung, gemäß erstem Ausführungsbeispiel,

Fig. 2

eine Herausvergrößerung der Fig. 1, die Position des Gelenkbolzens darstellend,

Fig. 3

die Zange in Seitenansicht, geschlossen,

Fig. 4

die Rückansicht der Zange,

Fig. 5

eine Seitenansicht der Zange mit gegriffenem Objekt,

Fig. 6

eine Herausvergrößerung, die dann vorliegende Position des Gelenkbolzens zeigend,

Fig. 7

eine Herausvergrößerung der Anlenkung der Feder,

Fig. 8

den Schnitt gemäß Linie VIII-VIII in Fig. 7,

Fig. 9

die Feder in Seitenansicht,

Fig. 10

die Feder in Draufsicht,

Fig. 11

die Zange in Seitenansicht, gemäß zweitem Ausführungsbeispiel, in federbelasteter Öffnungsstellung,

Fig. 12

die andere Seite der Zange zeigend in Stellung gemäß Fig. 11,

Fig. 13

diese Zange geschlossen,

Fig. 14

die Zange unter Greifen eines Objekts,

Fig. 15

die Feder dieser Zange in Seitenansicht,

Fig. 16

eine Draufsicht hierzu,

Fig. 17

die Zange in Seitenansicht, gemäß drittem Ausführungsbeispiel, in federbelasteter Öffnungsstellung,

Fig. 18

die Zange in Seitenansicht gemäß viertem Ausführungsbeispiel, in federbelasteter Öffnungsstellung,

Fig. 19

die Zange in Seitenansicht, gemäß fünftem Ausführungsbeispiel in federbelasteter Öffnungsstellung,

Fig. 20

die Zange in Seitenansicht, gemäß sechstem Ausführungsbeispiel, in federbelasteter Öffnungsstellung,

Fig. 21

den Schnitt gemäß Linie XXI-XXI in Fig. 20, vergrößert,

Fig. 22

die Zange in Seitenansicht, gemäß siebtem Ausführungsbeispiel, in federbelasteter Öffnungsstellung,

Fig. 23

die Feder in Einzeldarstellung, die Führungsanlenkung in dem einen Zangenschenkel zeigend,

Fig. 24

die Zange in Seitenansicht, gemäß achtem Ausführungsbeispiel, in federbelasteter Öffnungsstellung,

Fig. 25

diese Zange in Seitenansicht, geschlossen, ohne Objekt,

Fig. 26

die Zange in Seitenansicht gemäß neuntem Ausführungsbeispiel, in federbelasteter Öffnungsstellung,

Fig. 27

diese Zange in Seitenansicht, geschlossen, ohne Objekt.

The subject matter of the invention is explained below with reference to illustrative exemplary embodiments. It shows:

Fig. 1

the pliers in side view in the spring-loaded basic position, according to the first embodiment,

Fig. 2

1, showing the position of the hinge pin,

Fig. 3

the pliers in side view, closed,

Fig. 4

the rear view of the pliers,

Fig. 5

a side view of the pliers with gripped object,

Fig. 6

an enlargement, which then shows the present position of the hinge pin,

Fig. 7

an enlargement of the articulation of the spring,

Fig. 8

the section along line VIII-VIII in Fig. 7,

Fig. 9

the spring in side view,

Fig. 10

the spring in top view,

Fig. 11

the pliers in side view, according to the second embodiment, in the spring-loaded open position,

Fig. 12

showing the other side of the pliers in the position shown in FIG. 11,

Fig. 13

these pliers closed

Fig. 14

the pliers grasping an object,

Fig. 15

the spring of these pliers in side view,

Fig. 16

a top view of this,

Fig. 17

the pliers in side view, according to the third embodiment, in the spring-loaded open position,

Fig. 18

the pliers in side view according to the fourth embodiment, in the spring-loaded open position,

Fig. 19

the pliers in side view, according to the fifth embodiment in the spring-loaded open position,

Fig. 20

the pliers in side view, according to the sixth embodiment, in the spring-loaded open position,

Fig. 21

the section along line XXI-XXI in Fig. 20, enlarged,

Fig. 22

the pliers in side view, according to the seventh embodiment, in the spring-loaded open position,

Fig. 23

the spring in individual representation, showing the guide linkage in the one leg of the pliers,

Fig. 24

the pliers in side view, according to the eighth embodiment, in the spring-loaded opening position,

Fig. 25

these pliers in side view, closed, without object,

Fig. 26

the pliers in side view according to the ninth embodiment, in the spring-loaded open position,

Fig. 27

these pliers in side view, closed, without object.

The pliers 1 of all exemplary embodiments have two intersecting pliers legs 2 and 3. The latter are in the crossing area via a hinge pin 4 articulated against each other.

Above said crossing area of the pliers legs 2, 3 there is a pliers mouth M. Below the crossing area defined by the hinge pin 4 the pliers legs 2, 3 go into elongated handle sections 7, 8 over.

The hinge pin 4 passes through a longitudinal slot 9 of the Pliers leg 2. The hinge pin 4 is mounted in the penetrated pliers legs 3. The hinge pin 4 carries a pawl 10. This acts with tooth gaps 11 on the mouth side horizontal tooth profile of the penetrating Pliers legs 2 together. Fig. 2 shows that in Fig. 1st present release position, FIG. 6 that in FIG. 5 engaged latching position of this locking toothing. Longitudinal slot 9 and tooth gaps 11 can instead of the penetrating Pliers legs 3 formed his. In this case, the penetrated leg of the pliers corresponds 3 geometrically the pliers leg 2 in the attached drawing, only with the difference that these pliers legs then two across the longitudinal plane of the pliers spaced and provided with tooth gaps 11 slots having. In the vertical space between the elongated holes is the penetrating pliers leg, geometrically otherwise according to the pliers leg 2 trained according to the attached drawing, recorded.

To change the size of the jaws M shows the appropriate push-through connection a suitable Free space F. It is located on the pincer leg Third

The pliers 1 is open-mouthed via a spring drive 12 Basic position held (see Fig. 1, 11, 17, 18, 19, 20, 22, 24, 26). To do this, it works in the space between Pliers legs 2, 3 accommodated spring drive 12 spreading pliers legs. The end position is defined by Stop at the lower end of the slot-like longitudinal slot 9th

The spring drive 12 has a preload as a dash-dotted position in Fig. 1. Insofar the opening position is effective, but preloaded so that it can be overcome. Closing the spread pliers legs 2, 3 moves the jaw 6 of the sliding and pivotable pliers leg 3 in the direction the pliers jaw 5 of the penetrating pliers leg 2. This can be seen from Fig. 3. The open position 1 is accordingly understandable after relieving the grip sections 7, 8 of the pliers legs 2, 3 completely automatically by the described Spring-loaded.

The cross the gusset area of the pliers legs 2, 3 or bridging spring drive 12 also takes over Function of a control element 13. That protrudes, is supported from the penetrating pliers leg 2, on the gusset side freestanding. It forms a kind of cantilever, whereby in a first movement section of the spring drive 12 Forceps jaws 5, 6 to drive one another and in a second movement section an engagement of the pawl 10 of the hinge pin 4 in the locking teeth 11 he follows. After this, a force twist of the movable, thus penetrated pliers legs 3 or his Forceps jaw 6, going around the hinge pin 4, can be carried out. Overlapping movements take place here.

The spring drive / control element 12/13 provides the first two embodiments, a spring 14, more precisely a leg spring.

The ends of the spring 14 are each on one of the Pliers legs 2, 3 articulated. The articulation point on enforced pliers legs 3 is designated 15. It is a pivot point. The most assertive Pliers leg 2 is the articulation point 16. The geometric axes of the articulation points 15, 16 are parallel to the geometric axis of the hinge pin 4th

The spring 14 or leg spring has two spring sections different effective stiffness. The a spring section a is the more spring-friendly. The other spring section b. His Resilience can even go to zero. This Spring section b is assigned to the pliers leg 2.

The different resilience is based on different Lengths of the spring sections a, b made of wire, regardless of whether one of the spring sections is still in there is a (further) turn 17 such as that Embodiment of FIG. 11

The two are more stretched or curved Spring sections a, b assume a common spring turn 17 out. It lies on the hinge pin 4 facing side of the spring 14.

The spring articulation points 15, 16 are different arranged close to the pliers mouth M. So lies the articulation point 15 of the longer spring section a Forceps M closer. The approaching becomes even clearer with closed pliers 1 or with object handle. The corresponding Object, for example a pipe, is designated 18 (see e.g. Fig. 5). The leg spring springs out with respect to the spring turn 17 on the handle section side.

The articulation points 15, 16 and the end supported position the hinge pin 4 form an inherently stable hinge triangle, caused by the restoring force of the preloaded Spring 14. In this constellation, speak Basic position, the shorter spring section b is on the handle leg side supported. The support flank as a turning stop bears the reference number 19. It is such that the shorter spring section b only faces away from the pivot pin can pivot about its hinge point 16. From the support surface 19 goes one the end section close to the joint of the shorter spring section 9 securing nose 20.

The rotational mobility of the shorter spring section b is also limited in angle. It is a acute-angled free range of motion. The top The angle includes about 30 to 40 °.

As is clear from Fig. 7, the shorter one Spring section b also against a stop edge close to the edge 21 kick. Further pivoting this Section means resistance and so increased spring force the spring 14.

As can be seen from FIGS. 9 and 10, the spring forms 14 in the area of the spring turn 17 three turns out. These winding layers overlap one another at the edges under load, which favors the spring action i.e. elevated. The one that forms the longer spring section a The end is rolled into a bearing eye 22 at the end. The other end forms an angled bearing journal 23rd

The spring drive 12 is according to the second embodiment basically the same structure. The reference numbers are transferred analogously, without repeated text. The difference is that the spring 14 two Spring turns 17 provides. They are close together so that in principle there is an eight. They too selected there with respect to the shorter spring section b Support surface is designated 19. It stretches now instead of across, in the longitudinal direction of the penetrating Pliers legs 2. However, the shorter spring section b now strictly stretched, whereas he has an obtuse angle according to the first embodiment Kink shows. It is predetermined and can be found when it hits on the stop edge 21 even more concise train, so be included in the suspension.

Now to the pliers 1 according to the third embodiment. Here is instead of an integral design of the spring drive 12 set on a two-part. They are here too Reference symbols applied analogously, partly without text Repetitions. The control element 12 is there from a spring section a and a rigid section b '. In a figurative sense, this shorter spring section forms now a practically non-resilient element.

The spring section a is the outer end section of a Spiral spring 25. It takes a slightly arched, seen from the handle sections 7, 8 convex Course and passes into the bearing eye 22. The inner one End turn of the spiral spring 25 is on the rigid section b ' attached. The fixing is on a square 26 performed. The protrudes transversely from a handlebar 27. The Handlebar 27 can be formed in pairs, such that the wound section of the spiral spring 25 is covered, thus, as it were, receives a spring chamber.

The square 26 is fixed to the handlebar (s) 27 connected. The other end of the handlebar 27 is rotatable articulated on the penetrating pliers leg 2, also here forming the articulation point 16. This too Embodiment includes the provision that the shorter section of the spring drive 12, here the Rigid section b ', not going against the jaw M is supported by the Support flank 19 of the pliers leg 2 shown.

The function of the described pliers is as follows:

By closing the pliers legs 2, 3, the spring drive 12 in terms of his thighs in a stronger one V position brought, this against the restoring force the spring 14. The longer spring section a goes into a Almost the same position as the pliers leg 3 over. The jaw 6 runs in the direction the pliers jaw 5. Is now a through these jaws Object 18 gripped, the spring 14 folds in the direction the handle sections 7, 8 evasively. It is coming to leverage in that the pawl 10 in the tooth gaps 11 of the locking teeth occurs. It sets the described force rotation of the movable jaw jaw 6 one in the sense of a strong grasp. The shorter section of spring, be it springy or rigid, follows this buckling movement of the spring bridge. By releasing the object 18 is released and the Pliers 1 resume their spring-loaded, ready-to-grip Open position.

The spring is thus advantageously used that they also function as an actuator (Control element 13) takes over. Of course they can Feathers - as indicated - also in the form of a leaf spring be realized as the fourth according to FIG. 17 Embodiment is also apparent. With empty Closing the mouth M essentially only springs the one, longer spring section a using a stored in the form of turns 17 (see also FIG. 18) Spring force reserve. The shorter section of the spring practically remains in its through a support flank given basic position. In contrast, becomes a gripping object gripped by the mouth M of the pliers 1, so takes place in a kind of reverse thrust over the longer spring section a a pivoting of the shorter spring section b instead, be it that it also springs or is rigid.

Instead of an essentially V-shaped one, as shown The course of the spring 14 is also an S-shaped course conceivable (see FIG. 18), with the S-web the spring turn 17 has. The longer spring section is a aligned as shown in the exemplary embodiments, whereas the shorter spring section b is a U-turn 28 takes in the direction of the pivot pin 4. This Spring section is a little longer and also spring joyful. Here there is preferably a balanced aspect ratio before, whereas the illustrated embodiments a ratio between a: b of about 3: 1 having. The winding cavities can be in all Embodiments by push-button connectable Plates or buttons must be closed.

The fifth embodiment shown in FIG. 19 the pliers 1 is the pliers according to the third embodiment structurally close, the control element 13 from a combination spring section a and Rigid section b '. The one provided here Rotary stop in the form of a support flank 19 secures the Fold-out folding movement of the spring drive 12. The Reference numbers are used analogously, in part without repeated text.

19 shows a paired arrangement of the handlebars 27. They extend congruently and circumscribe practically a teardrop shape. In the closer Zone is the articulation point 16 to the pliers leg 2 out.

By spacing the two links 27 from each other is considered a free space in which the spring turn 17 of the spring 14, realized as a torsion spring, under coming. The winding package of the spring winding 17 is tied up in the spring chamber thus created. Reached is the corresponding spring attachment by a Support pin 29. The crosses the pair of handlebars 27 and penetrates the winding package of the spring 14. The support pin 29 can be dimensioned so that under Consideration of the mobility of the spring turn 17 there is a non-slip holder.

As can be seen from the drawing in FIG. 19, the Spring section b not continuously to the articulation point 16 trained; rather, it is within the open space the pair of links 27 supported. The Spring section b occurs against a pin 30, which is spaced from the support pin 29 the spring chamber formative free space. The ends of the cones 29 and 30 are in the plate-shaped parts of the handlebar 27 attached.

Such a torsion spring is also the sixth Embodiment used. It is on the figures 20 and 21 referenced. This spring 14 is knee-like interconnected rigid sections b 'assigned. The knee joint there bears the reference symbol 31. The mutually pointing ends of the two rigid sections b 'are via articulation points 15, 16 with the Pliers legs 2, 3 articulated. The buckling direction the knee joint is also facing away from the mouth.

The two rigid sections b 'are of nested U-profile sections formed. In the area of the knee joint 31 is on a stop-forming Attention overlap of the ends there. The results in a defined, caused by the spring 14 Stretching position of the two rigid sections b '. This one both spring sections labeled a act accordingly in the direction facing away from the mouth Rigid sections b '.

The pliers legs 2, 3 or their grip sections 7, 8 spreading spring drive 13 is still here by another arranged on the handle section 8 Spring 32 supports. Accordingly, it works in the same direction with regard to the stretched position of the rigid section b 'to each other, which are so well biased. In terms of the stretched position is that the two Rigid sections in the stretched state between them an opening angle of less than 180 ° on the mouth side lock in. The knee-like interconnected Rigid sections b 'can therefore only face away from the mouth buckle. The knee pivot 31 can not in one Dead center position between the articulation points 15 and 16 occur. All other spring drives 12 can only face away from the mouth buckle, e.g. because of the handle section accordingly Curvature or an angular course of rigid section b 'and spring section a.

The further spring 32 is with one over the articulation point 15 outgoing rigid section b '' connected. This rigid section b '' gives the rigid section b ' a double-armed figure. The spring 32 is a tension spring. In return, the shorter arm of the double-armed could Rigid section b '/ b' 'there also as a compression spring attack. The spring 32 expediently comes in the free space F of the pliers leg 3 under.

The pliers 1 according to the seventh embodiment (cf. 22) has a bow spring B as the spring 14 on. It has two bracket arms 33, 33 '. The one as it were closed U forming bow spring B has a relative briefly designed bow turn 33 ''. The bow arms 33, 33 'are of different lengths. The one labeled 33 is the shorter arm. assessment basis is the bend that lies across the bracket arms 33 ".

The bow spring B provides the spring drive 12 at the same time the handlebar-like control element 13. The latter is with respect to a plane of symmetry of the pliers 1 inclined. In the seventh embodiment extends the bow turn 33 '' in a more distant position than the cantilevered ends of the two bracket arms 33, 33 '. In the mentioned embodiment, the bracket arms 33, 33 'on the pliers leg designated by 3 forming joints supported. The bow turn is 33 '' supported on the pliers legs designated by 2. In this respect, the joint point on the pliers leg 3 has two digits. The articulation point for the shorter arm 33 bears the reference numeral 15 'that of the longer bracket arm 33 'the symbol 15' '. The latter articulation point is located maul closer.

The other end of this control element 13 is as a hairpin U-shaped. The bow turn 33 "acts as a torsion spring bar.

The bow turn 33 '' is supported on the pliers leg 2 and guided longitudinally. It crosses an elongated hole 34 of the pliers leg 2 and is included. The Slot 34 is of such a length that when biting the pliers 1 the corresponding evasive movement can be carried out is. The corresponding evasion of the Control element 13 is not shown because it is light imaginable.

By approaching the handle sections 7, 8 change the articulation points 15 ', 15' 'spatially to each other by which is still an acute-angled in the position according to FIG. 22 Bracket arms 33, 33 'having a spreading position each other approach. The longitudinal constraint that occurs on shorter arm 33 stores more spring force that already exists from a certain preload. This total force results after the handle sections are released 7, 8 always to bring about the Fig. 22 apparent open position. Under the pivoting the pliers legs 2, 3 support the U-shaped bend 33 '', acts as a movable articulation point 16 'at first.

The support of the U-shaped bend 33 "is achieved through profiling, specifically through a to the longitudinal direction of the pliers leg 2 inclined initial support surface underlining the bow turn 33 '' 36th

Alternatively, the bow spring B can simply be attached the inside of the pliers leg 2 on a rail guided support. The bow turn 33 '' only needs have a corresponding leadership profile, For example, in the form of a W-shaped fold of the wire Bow spring B. The rail could be in the open position 22 defining lug 38 exhibit.

The eighth embodiment is based on FIG. 24 again on a combination of spring section a and Hard section b ', here again provided by one Handlebar 27. The reference numerals are, as far as understandable required, applied analogously here again partly without repeated text.

However, the seventh is used here Embodiment bow spring described in detail B. But the reverse is now assigned, and so that that the bracket arms 33, 33 'on a pair of pliers, namely the pliers leg designated 2, rotatable Stored section b 'attacks or supported is. Here, as it were, there is indirect support the pen. The cantilevered arms 33, 33 'are also rotatable on different axes of rotation self-rotating rigid section b 'mounted. recognizable here are differently long bracket arms 33, 33 'before. The shorter bracket arm 33 lies here the mouth M closer to the pliers 1. The bracket arms 33, 33 'also give this embodiment by operating the pliers 1 in an overlap position, caused by the steering around Articulation point 16 pivoting rigid section b ', that is Handlebar 27. The handlebar-side axes of rotation are included here 16 'and 16' 'respectively.

Forming axes with respect to the pivot points at both Solution according to the seventh embodiment as well those according to the eighth embodiment are angled inward, ends overlapping one another, forming plug pins 39, 39 '(see Fig. 23).

The loop turn 33 ″ takes on the object according to FIG. 24 a helical course. It is a camp eye 40 designed. Its cavity penetrates the Joint 15 bringing the pin.

The bow arms 33, 33 'can have a curved course have so that under that by turning the handlebar 27 publishers of the rotary axes 16 ', 16' ' the also energy-storing bulge of the compressed Arm arm in the corresponding predetermined direction goes. If there is a preload from the start The stretching pull on it also has a low spring force. One against the forceps-supported triple constellation the movement of the articulation points reacts as a restoring effect, with a bias contributes, the rigid section b 'in the basic position stops at the rotation stop of the pliers leg 2, so on the support surface 19. The curvature is at least on a bow arm facing the pliers mouth M concave.

With reference to Fig. 24, it is understandable that here too as in all other embodiments, the mouth away Buckling movement takes place. 25 shows the closing of the mouth without having an object in it to have. It is clear that when the mouth is filled, M the pincer leg designated 3 further down the mouth is shifted so that the rigid section b 'in the shown in dash-dotted line style in FIG Alignment shifted. The line bears the reference symbol 41st

The ninth embodiment corresponds essentially that of the eighth embodiment. However lies now again based on a toggle-type solution. It is the articulation of the bow spring B from the seventh embodiment taken over, i.e. formation of the articulation points 15 ', 15' 'on the pliers leg 3. This is how that on the rigid portion b 'with the spring 14, the bow spring B, so cooperating stop 42 is formed. It sits as the outside of the Handlebar 27 outstanding pin on this and hits against the side of the bow spring B facing away from the mouth M The bow turn 33 '' represents the knee pivot here 31. Grasping an object 18 kicks the knee-like Spring drive / control unit 12/13 facing away from the mouth off, also here in the green position an extended position having the buckling only in this direction allows.

Claims (15)

1. One-handedly actuatable, self-closing pliers (1) having two pliers limbs (2, 3) which are interconnected in a crossing region by means of a articulation pin (4), a pliers mouth (M) being formed on one side of the crossing region of the pliers limbs (2, 3) and grip sections (7, 8) being formed on the pliers limbs (2, 3) on the opposite side below the crossing region, one pliers limb (3), which can be adjusted in the crossing region relative to the other pliers limb (2) in order to vary the size of the pliers mouth (M) having a free space (F) which is penetrated by the other pliers limb (2), or the non-adjustable pliers limb being penetrated by the adjustable pliers limb and, furthermore, the pliers limbs (2, 3) being connected via a control element (13) and a spring drive (12) which biases the pliers mouth (M) into an open position, which open position is produced automatically under spring loading after unloading of the grip sections (7, 8), wherein, in addition, the pliers mouth jaws (5, 6) move towards one another in a first movement section of the spring drive (12), and a pawl (10) of the articulation pin (4) engages in a latching tocth arrangement (11) in a second movement section, whereafter a forced rotation of the movable pliers mouth jaw (6) about the articulation pin (4) can be carried out, characterized in that the spring drive (12) simultaneously fulfils the function of the control element (13), this spring drive (12) being composed of a spring (14) with two spring sections (a, b'), one spring section (b') being formed as a rigid section (27), the rigid section (27) being connected to the other pliers limb (2), and the spring section (a) being connected to the adjustable limb (3), a rotation stop (19) for the rigid section (27) being provided on the other pliers limb (2) such that in the unactuated state the rigid section (27) engages against the rotation stop (19) provided on the other pliers limb (2), and in that, upon displacement of the adjustable pliers limb (3) into a mouth closing position gripping a workpiece, the rigid section (27) comes clear of the rotation stop (19) only after forced actuation with the pliers mouth jaws (5, 6) engaging against the workpiece.
2. Pliers according to Claim 1, characterized in that the rigid section (b') is a link (27) at one end of which the spring element is secured, and whose other end is rotatably disposed on the pliers limb (2).
3. Pliers according to Claim 2, characterized in that the link (27) is of paired construction and leaves a free space for the spring (14) and the spring fastening by spacing the two links (27).
4. Pliers according to one of Claims 1 to 3, characterized in that the spring section (a) is formed by a spiral spring (25).
5. Pliers according to Claim 3 or 4, characterized in that the spring fastening is achieved by a bearing pin (29) which penetrates the turn packet of the spring coil (17) and connects the links (27).
6. Pliers according to one of Claims 1 to 5, characterized in that the spring section (b) facing the rigid section (b') of the spring (14) formed as a rotary leg spring is supported on the rigid section (b').
7. Pliers according to Claim 6, characterized in that the support is formed by a pin (30) likewise connecting the links (27).
8. Pliers according to one of Claims 1 to 7, characterized in that the spring (14) is formed as a bow spring (B) with bow arms (33, 33') and a bend of the bow (33''), the bow arms (33, 33') or the bend of the bow (33'') being rotatably supported on one pliers limb (2) by means of the positioned rigid section (b').
9. Pliers according to Claim 8, characterized in that the bow arms (33, 33') are rotatably supported on a rigid section (b') or a pliers limb (2 or 3) via different fulcrums (15', 15'', 16', 16").
10. Pliers according to either of Claims 8 and 9, characterized in that the bow arms (33, 33') are formed to be of different lengths.
11. Pliers according to one of Claims 8 to 10, characterized in that the bow arms (33, 33') have a curved profile.
12. Pliers according to Claim 11, characterized in that the curve is concave facing the pliers mouth (M).
13. Pliers according to one of Claims 8 to 12, characterized in that the bend of the bow (33'') is U-shaped.
14. Pliers according to one of Claims 8 to 12, characterized in that the bend of the bow (33'') is helical.
15. Pliers according to one of Claims 1 to 14, characterized in that a stop (42) cooperating with the spring (14) in the expanded position of the spring drive (12) is provided on the rigid section (b').

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