RU2484942C2 - Hand-held gripper - Google Patents

Abstract

FIELD: process engineering.

SUBSTANCE: invention relates to hand-held grippers. Proposed hand-held gripper comprises first and second jaw assemblies with section of engagement with gripped part. Second jaw assembly can displace relative to first jaw to form variable-size spacing for part to be gripped between engagement sections. Besides, gripper comprises handle to apply force to second jaw assembly. Second jaw assembly can be engaged with the surface of response to press engagement section to gripped part. Second jaw assembly comprises longer section extending from said engagement section with gripped part. Handle arm is connected to said extended section at the point of connection while the latter incorporates section of facilitating flexure. The latter is located between aforesaid engagement section and aforesaid point of connection. Said flexure facilitating section facilitates longer section flexure in direction from first jaw assembly. In compliance with second version, gripper comprises first and second cams. In compliance with third version, gripper comprises rotary lever means.

EFFECT: reliable gripping.

25 cl, 13 dwg

Description

The present invention relates generally to hand tools for gripping, and in particular to hand tools for gripping, which allow you to adjust the size range between the jaws of the tool to any size of the clamped part. One of the most applicable forms of hand tools for gripping are tongs of this type, which are called pipe tongs or slotted tongs.

BACKGROUND OF THE INVENTION

Known pipe clamps have a common characteristic, namely that the jaws are located at an angle to the clamp handles, and the articulated finger, in the form of a bolt or rivet, is installed in the area behind the sponge on one of the handles and protrudes through an elongated groove on the other handle. In such pincers, various means for selectively changing the distance between the jaws can be in the form of protrusions or teeth offset from one another, provided along the inner long edge of the groove and adapted for increasing selective binding engagement with the articulated finger. Another well-known way of adjusting the distance between the jaws in such pincers is the use of protruding protrusions from each other on the facing surfaces of the groove for introducing the articulated finger. In all such tools, two-handed operation is required to adjust to the size of a particular part clamped between the jaws. With this adjustment, the handles are moved apart so that the pivot pin can slide along the groove to move one of the jaws to a position roughly corresponding to the desired size of the clamped part.

Other known types of mites are adapted for sliding locking on the clamped part in response to manually bringing the handles together and, in response to contact with the clamped part, for automatically blocking the further sliding action, due to the engagement of the corresponding teeth and, due to this, for transition from sliding mode to turning mode, as a result of which further application of manual force to the handles increases the action of the clamp on the clamped part.

This clamping action in known pliers is a function of the relationship between the length of the working handles and the length of the jaw from the articulated finger, which is typically about 5: 1. Therefore, a substantial proportion of the torque applied to the work handles is required to clamp the workpiece to be clamped, which means that often there is insufficient torque to rotate the tightly clamped part.

In some circumstances, it is highly desirable that the pliers can be locked (locked) on the clamped part. Known ticks do not allow such a function.

Another disadvantage of the known pincers is that the action of fixing the articulated finger by means of offset protrusions, teeth or arcuate protrusions in the groove is such that the jaws / handles are rarely in the optimal position before switching from sliding to turning mode . This results in a variable gripping action of the clamped part.

SUMMARY OF THE INVENTION

In accordance with the present invention, there is provided a hand gripping tool that comprises a first jaw assembly having an engagement portion with a clampable part, a second jaw assembly having an engagement portion with a clampable part and configured to move relative to said first sponge assembly so that a variable space is formed the size for receiving the clamped part between the indicated sections of engagement with the clamped part, and a handle for applying force to the specified node of the second jaw, the second jaw assembly is adapted to engage with the reaction surface, so that, when applied, in response to the indicated force applied by the handle, its engagement portion with the clamped part is pressed against the clamped part inserted into the space for receiving said clamped part, and which comprises an extension section extending from said section of engagement with the clamped part, said lever arm being connected to said extension section at a junction, said extension section has a bending assistance portion located between said engagement portion with the clamped part and said junction, wherein said bending assistance portion is configured to facilitate limited bending of the extension portion in the direction of removal from said first jaw assembly in response to a reaction force generated by engagement with the specified clamped part between the specified nodes of the first and second jaws.

The present invention also provides a hand grip tool that includes a first jaw assembly, a second jaw assembly, a first cam connected to said first jaw assembly, a rotary handle for applying a working force to said first jaw assembly, and a second cam connected to said a rotary handle, wherein said nodes of the first and second jaws are configured to interact to form a variable-sized space for receiving a clamped part, and said first and second cu the tabs are operable in response to said application of a working force to induce said nodes of the first and second jaws to clamp said clamped part which is located in the indicated space of variable size, wherein at least one of said nodes of the first and second jaws contains a bending assistance section made with the possibility of facilitating the bending of the jaw assembly in the direction of removal from the specified space of variable size in response to the reaction force created by the clamped part, sandwiched between the indicated nodes of the first and second jaws in the indicated space of variable size.

The present invention also provides a hand-held gripping tool that comprises a first jaw block, a second jaw block configured to interact with said first jaw block to form a variable-sized space for receiving a clamped part, support means on which said block is first the jaw can slide to resize the specified space for receiving the clamped part, and a pivoting lever means, moreover, both the specified block of the first jaw and the specified the gate lever means are provided with an engagement means for engaging with corresponding parts on said support means, so that a rotation movement of said lever means in one direction causes said first jaw block to move in the direction of the clamped part, which is located in said space for receiving the clamped part, at least mainly in contact with said first and second jaw blocks to clamp said part, said first jaw block being drawn out it is capable of performing a limited bending movement in the direction of removal from the specified space for receiving the clamped part in response to the reaction force created by the specified part, sandwiched between the said blocks of the first and second jaws in the indicated space of variable size.

The above and other characteristics of the invention will be more apparent from the following detailed description of some of its variants, given as an example with reference to the accompanying drawings.

Brief Description of the Drawings

Figure 1 shows the first embodiment of a hand tool for gripping with some conventionally removed layers, and the automatic locking device of the tool is in working, but not locked state.

Figure 2 shows the first option with some conventionally removed layers, and the automatic locking device is in a locked state.

Figure 3 shows the first option with some conventionally removed layers, and the automatic locking device is in the allotted inoperative state.

Figure 4 shows with increasing the plot of figure 3, where the node of the movable jaw is shown in more detail.

Figure 5 shows a second embodiment of a hand tool for gripping a clamped part such as a fastener, with a conventionally removed layer of a sponge assembly, to show the inside of the tool.

FIG. 6 shows a third embodiment of a hand held gripping tool that loosely holds a fastener, such as a fastener, with a conditionally removed layer of a jaw assembly to show internal parts of the tool.

7 shows a third embodiment in a locked state, with a conditionally removed upper layer of the connecting lever to show the internal details of the tool.

On Fig shows a fourth embodiment of a hand tool for gripping, when clamping two plate parts together, with a conditionally removed connecting element to show the internal parts of the tool.

Fig. 9 shows a fifth embodiment of a hand gripping tool, with a conditionally removed connecting element, to show the internal details of the tool.

Figure 10 shows a fifth embodiment after partial actuation, when its jaw assemblies come into contact with the clamped part.

11 shows a fifth embodiment, but in a different operating position and when gripping a clamped part of a different type.

12 shows a sixth embodiment of a gripping hand tool open to receive a fastener with a connecting member removed to show the inside of the tool.

On Fig shows a sixth embodiment corresponding to Fig, but with a tool clamped on the clamped part.

DETAILED DESCRIPTION OF THE INVENTION

In the following description of hand gripping tool options, similar tool parts will have the same reference numerals.

Figures 1-4 show a first embodiment of a hand grip tool in the form of pincers 1. Pliers 1 comprise a fixed jaw assembly 2a, a movable jaw assembly 2b, a fixed handle 3, and a rotary handle 4. Each jaw assembly 2a, 2b has an engaging portion to be clamped a part having a corresponding sponge grip profile 2g, 2f. The movable jaw assembly 2b can be moved relative to the fixed jaw assembly 2a due to the action of the rotary knob 4 to create a variable-sized space for receiving a clampable part between the jaw gripping profiles 2g, 2f. The nodes 2A, 2b of the jaws, the fixed handle 3 and the rotary handle 4 can be made in the form of layered structures. 1-4, the uppermost (in the drawings) layers are conventionally removed to show the internal details of the ticks 1.

The fixed jaw assembly 2a is connected to the support member 3 for the movable jaw assembly 2b. The supporting element 3a extends laterally with respect to the fixed jaw assembly 2a (in this embodiment, the supporting jaw element is approximately perpendicular to the fixed jaw assembly 2a). The movable jaw assembly 2b is slidable along the support member 3a to resize the space for receiving the clamped part. The support member 3 forms a first clamping surface or reaction surface 3b and a second clamping surface or reaction surface 3c. The first and second clamping surfaces 3b, 3c are offset from each other and face in opposite directions. The fixed handle 3 is connected to the end of the support member 3a, so that the support member extends between the fixed handle 3 and the fixed jaw assembly 2a.

The movable jaw assembly 2b is a layered structure that comprises a central jaw member 2h and an extension portion that includes two elongated connecting members 5e. 1-3, the uppermost (in the drawings) connecting element 5e is conventionally removed to show the internal details of the tongs 1. The movable jaw assembly 2b comprises a cam surface 2c that is formed in the central jaw member 2h and may engage with the first clamping surface 3b. The connecting elements 5e are attached to the sides of the central jaw element 2h, so that the central jaw element is sandwiched between the connecting elements. The portions of the connecting elements 5e that are attached to the sides of the central jaw element 2h have a shape corresponding to the profile of the central jaw element and thus comprise jaw gripping profiles 2f, 2g. The connecting elements 5e extend from the central jaw element 2h and are offset from each other so that a gap is formed between them. The support member 3a extends through a gap formed between the connecting members 5e. The rotary knob 4 is rotatably connected to the movable jaw assembly 2b using a pivot pin 6 at a junction located near the respective free ends of the connecting elements 5e.

As shown in FIG. 4, the connecting elements 5e comprise a bending assistance portion 5f. When the movable jaw assembly 2b is assembled with the support member 3, a bending assistance portion 5f is disposed between the first clamping surface 3b and the connection point in which the pivot handle 4 is connected to the movable jaw assembly 2b by a pivot pin 6. In particular, in the illustrated embodiment, the portion 5f bending assistance extends between the cam surface 2c and the second clamping surface 3c. The bending assistance portion 5f comprises a curved or corrugated section that is curved in the general direction of the fixed jaw assembly 2a. The bend is in the plane of the coupling elements 5e.

As shown in FIG. 1, the pivot handle 4 comprises a pivot cam 4at of the pivot handle that is located on the pivot handle adjacent to the pivot pin 6, so that when the pivot handle pivots on the pivot pin, the cam 4at pivots about the axis of the pivot pin. The teeth of the rotary knob gear cam 4at mesh with the toothed sliding shoe 17t, which engages with the second clamping surface 3c and is slidable along it.

The pivot link 12 extends between the fixed handle 3 and the pivot handle 4. The pivot link 12 is pivotally connected to the fixed handle 3 using a pivot pin 12b that slides into the groove 3e formed in the fixed handle 3. The groove 3e runs along the length of the fixed handle 3 and when the topmost (in the drawing) layer of the handle is in place, it cannot be seen. The pivoting link 12 is pivotally connected to the pivoting knob 4. The bias member in the form of a tension spring 8 is connected to the pivoting pivot 12a and to the attachment point on the pivoting knob 4 and allows the pivoting knob to be shifted to the position shown in FIG. one. 1, the pliers are shown in a fully open state in which the space for receiving the clamped part formed between the jaw nodes 2a, 2b has a maximum size.

The pincers 1 comprise an automatic locking device that has teeth 22 provided at the end of the pivoting link 12 adjacent to the pivot pin 12a, and the pivoting element 24. The pivoting element 24 is pivotally mounted on the pivoting handle 4 with respect to the pivot pin 26. The pivot pin 26 is stationary relative to the rotary handle 4 and passes through a groove 27 (figure 2), elongated along the length of the locking element 24. The locking element 24 has a protrusion 28 for the thumb, which can be pressed by the user of the pliers 1. When the upper layer of the rotary handle 4 is in place, the protrusion 28 for the thumb is the only part of the locking element 24, which is visible.

As is shown particularly well in FIGS. 2 and 4, teeth 30 are provided on the end of the locking member 24 opposite to the thumb protrusion 28 on the side facing away from the finger 6 of the rotary handle, for engaging with the teeth 22 on the rotary link 12. On the other side of the locking element 24, opposite the teeth 30, there is a recess, which includes the end of the elastic element, which in this embodiment is a compression spring 32. The opposite end of the compression spring 32 is held in a recess 34 provided in the rotary handle 4. As best shown in FIG. 4, the serrated end of the locking element 24 is provided with a sharp protrusion 36, which is included in the recesses 38, 40 provided in the rotary handle 4, to install the locking element 24 in its idle and working position, respectively. The compression spring 32 biases the locking element 24 to the operating position shown in FIGS. 1 and 2, in which the protrusion 36 enters the recess 40, while the locking element 24 automatically engages with the teeth 22 provided at the end of the pivot link 12. When the protrusion 36 is inserted into the recess 38, the locking element is held in a retracted (inoperative) position in which it cannot engage with the pivoting link 12. Thus, the locking element 24 can be locked in the retracted inactive position. This means that, if desired, pliers 1 can be used without an automatic locking device. When the user wishes to actuate the automatic locking device, he uses the thumb protrusion 28 to slide the locking element 24 outward relative to the rotary knob 4 to withdraw the protrusion 36 from the recess 38. As soon as the protrusion 36 is removed from the recess 38, the compression spring 32 starts act on the toothed end of the locking element to move the locking element to the operating position shown in figures 1 and 2, in which it is ready for automatic engagement with the rotary link 12.

In figure 2, the teeth 30 of the locking element 24 are shown in meshing with the teeth 22 on the pivot link 12, as a result of which the jaw units 2a, 2b are locked in the position shown. The teeth 22, 30 are shaped so that when the pivot link 12 pivots from the position shown in FIG. 1 to the position shown in FIG. 2, they automatically engage, similar to a ratchet mechanism. The bias force created by the compression spring 32 forces the teeth 30 to mesh with the teeth 22, whereby the locking engagement is maintained.

The lock can be removed by pressing downward (as shown in FIG. 2) on the protrusion 28 for the thumb so that the toothed end of the locking element 24 rotates counterclockwise in order to release the rotary link 12 and allow the free movement of the rotary handle 4 relative to the fixed handle 3. When releasing the protrusion 28 for the thumb, the toothed end of the locking element 24 returns to the position shown in figure 1, so that the locking element is ready to automatically engage with the teeth 22 company level 12.

It has been found that the bending assistance portion 5f improves the operation of the tongs 1. It should be borne in mind that when the movable jaw assembly 2b engages with a clamping member gripped between the jaw gripping profiles 2f, 2g, considerable force may be required by the user to the rigid unit 2b of the movable jaw grips the clamped part so that the teeth 22 on the pivot link 12 are fully engaged with the teeth 30 on the locking element 24. This is especially true when the jaw nodes 2a, 2b and the clamped part are made s are made of solid material and are tough. If the relevant parts are hard and rigid, there is a risk of incomplete engagement of the teeth 22, 30 and slipping of the lock. By creating a limited bend of the engagement portion with the clamped part of the movable jaw assembly 2b in the direction away from the clamped part, additional force can be applied by the user to the rotary handle 4, due to which additional handle movement can be created to fully engage the teeth 22, 30 This makes it easier for the user to lock and reduces stress in the movable jaw.

Turning now to FIG. 4, a recess 2m is shown, which may be provided in the fixed jaw assembly 2a. This allows you to further increase the bending of the nodes 2A, 2b of the jaws and further reduce the force introduced by the user in order to block the nodes 2A, 2b of the jaws when tightly engaged with the clamped part.

It should be borne in mind that the configuration of the bending assistance portion 5f and, if any, the recesses 2m can vary significantly to provide the desired degree of bending. For example, the bending assistance portion 5f may have a single arc in the space direction for receiving the clamped part. However, other arcs, undulations or corrugations in the plane of the connecting elements 5e may be provided. It should also be borne in mind that the degree of permissible bending should be relatively small, since otherwise the mites 1 will not be able to produce the proper clamping action. The degree of required bending, acceptable for the satisfactory operation of ticks 1, can easily be determined by experiment.

If necessary, the first and second clamping surfaces 3b, 3c provided on the support element 3 may not be parallel. Instead, the first clamping surface 3b may slope toward the second clamping surface 3c when the two surfaces approach the fixed jaw 2a. This narrowing of the support member 3a is shown in FIG. The wedge effect created due to this causes the cam 2c of the movable jaw assembly to act faster and lock better. This also reduces the likelihood of partial closing of the jaw angle when clamping a thin clamped part, since thinning of the support element 3a in the direction of the fixed jaw assembly 2a can nullify the effect of any rotation of the gear cam 4at of the rotary handle relative to gear shoe 17.

Figure 5 shows a second embodiment of a hand grip tool in the form of pliers 1. The pliers 1 are shown in a closed state when gripping a clamped part such as a fastener between the jaw assemblies 2a, 2b. The uppermost (in the drawing) connecting element 5e is conventionally removed to show the internal details of the pliers 1.

In the second embodiment, the support element 3a extends generally perpendicular to the first jaw assembly 2a and has first and second clamping surfaces 3b, 3c, which are mainly parallel, spaced apart from each other. The groove 3d goes along the length of the support element 3A. The sliding finger 7 passes through the groove 3d generally perpendicular to the plane of the support element 3a and is held in the corresponding bushings provided in the connecting elements 5e. The finger 7 can slide along the groove 3d when the second jaw assembly 2b slides along the support member 3a. An elastic element in the form of a tension spring 8 is inserted into a groove 3d. One end of the spring 8 is attached to the fixed jaw 2a by means of a finger 9. The opposite end of the elastic element 8 is attached to the sliding finger 7. The spring 8 pulls (attracts) the second jaw assembly 2b in the direction of the first jaw assembly 2a, so that the tongs 1 are biased into the closed state and create a slight clamping force applied to the clamped part 11a before applying the force F to the rotary handle 4.

The rotary knob 4 comprises a cam 4a associated therewith, which acts on the second clamping surface 3c of the support member 3a to cause the cam 2c of the second jaw assembly 2b to rotate relative to the first clamping surface 3b. The rotary knob 4 also contains corresponding abutment surfaces 4d, which can engage with the stops 5d, which protrude from the connecting elements 5e and serve to limit the movement of the rotary knob 4 in the direction of removal from the stationary handle 3.

Next, a description will be given of five other options for a hand grip tool in the form of pincers 1, each of which has an element for facilitating bending on one or two nodes of the jaws. These options show how the concept of bending assistance can be incorporated into various configurations of a gripping hand tool, and the description of these options further illustrates the functioning of the first option.

Figures 5 and 6 show a third embodiment of a hand grip tool in the form of pincers 1, the uppermost (in the drawing) connecting lever 5e being conventionally removed to show the internal details of the tool.

6, the rotary knob 4 is shown in the fully open position. In this position, the cam 4a on the rotary handle 4 is disengaged from the sliding shoe 17 and the cam surface 2c is offset from the first clamping surface 3b (there is a gap Ga). In this state of the pincers 1, it is only necessary to overcome the tension of the elastic element 8 to rotate the jaw nodes 4a, 4b in order to translate the jaw gripping profiles 2e, 2f into the gripping state of the clamped part 11a.

The slip shoe 17 is in the shape of a cross. The sliding shoe 17 is held between the cam 4a on the rotary handle 4 and the second clamping surface 3c due to the fact that the branches 17a of the sliding shoe enter into corresponding grooves (not shown) in the connecting elements 5e. Thus, the slip shoe 17 is forced to move with the movable jaw assembly 2b when it slides on the support member 3a.

Between the cams 4a, 2c has a distance D2.

Fig. 7 shows a third embodiment, with the rotary handle in the fully closed position, when the jaw units 2a, 2b clamp the piece 11c in the form of two plates. The movement of the rotary handle 4 to the fully closed position causes the cam 4a to rotate behind the sliding shoe, whereby the locking surface 4b comes into close contact with the second clamping surface 3c through the sliding shoe 17. The cam 4a on the rotary handle moves the movable jaw assembly 2b on the cam surface 2c so that the locking portion 2d of the movable jaw assembly 2b is engaged with the first clamping surface 3b above the center of the pivot pin 6, at a distance D1. This arrangement does not allow the rotary handle 4 to move outward relative to the stationary handle 3, except for such a manual movement. This blocks the tongs 1 in the gripping position of the clamped part 11c.

Fig. 8 shows a top view of a fourth embodiment of a gripping hand tool made in the form of pincers 1. And in this case, the upper (in the drawing) connecting element 5e of the movable jaw assembly 2b is conventionally removed to show the internal details of the pincers 1.

In this embodiment, the fixed handle 3 is directly connected to the fixed sponge 2a. The elastic element 8 is not in the elongated groove of the support element 3a. Instead, it is held between the respective spring struts 9 provided on the fixed jaw assembly 2a and the movable jaw assembly 2b. The elastic member 8 biases the movable jaw assembly 2b toward the fixed jaw assembly 2a and presses the cam 4a on the rotary handle 4 to the second clamping surface 3c when the tongs 1 are at rest. In this embodiment, there is no slip shoe, so that the cam 4a abuts directly against the second clamping surface 3c.

In Fig. 8, the rotary handle 4 is shown fully rotated in the direction of the fixed handle 3, whereby the locking portion 4b of the locking of the rotary handle 4 is in close contact with the second clamping surface 3c, so that the jaw assemblies 2a, 2b will be clamped on the clamped part 11c.

Figs. 9-11 show a fifth embodiment of a gripping hand tool made in the form of pincers 1. In Figs. 10 and 11, the upper layer 3g of the fixed handle, the upper layer 4e of the rotary handle and the upper connecting element 5e are conventionally removed.

9, ticks 1 are shown at rest. The elastic element 8 acting on the rotary handle 4 and the rotary link 12 causes the movable jaw assembly 2b to move down the support member 3, in the direction of removal from the fixed jaw assembly 2a. This biases the cam surface 2c from the first clamping surface 3b, so that a gap Ga is formed. The stop 4d on the rotary handle 4 acts on the stop 5d on the connecting element 5e, to limit the movement of the rotary handle. The cam 4a on the rotary handle 4 is offset from the second clamping surface 3c.

In figure 10, the rotary handle 4 is forcibly mixed in the direction of the fixed handle 3 due to the action of the force F, which causes it to rotate relative to the rotary link 12, overcoming the resistance of the elastic element 8, until this movement is stopped by the nodes 2A, 2b of the jaws included in contact with the fastener 11a. During this part of the movement, the initial engagement of the cam 4a on the rotary handle 4 with the second clamping surface 3c does not create an effective clamping action of the fastener 11a.

11, the pivot handle 4 and pivot links are shown in the fully actuated position, causing the jaw units 2a, 2b to clamp the tubular clampable part 11b. The force F applied to the pivot handle 4 causes the pivot pin 12b to move downward into the groove 3e in the fixed handle 3, thereby elongating the elastic member 8. This allows the pivot handle 4 to rotate around the pivot pin 6, causing the cam 4a on the pivot handle to act on second clamping surface 3c. This action rotates the movable jaw assembly 2b on the cam surface 2c and biases the locking portion 2d in the direction of the first clamping surface 3b, which further enhances the clamping effect of the jaw assemblies 2a, 2b on the clamped part 11b. This allows significant torque to be applied to rotate the part 11b, while a lower force F is required so that the jaw assemblies 2a, 2b continue to clamp the part 11b.

12 and 13 show a sixth embodiment of a gripping hand tool made in the form of pincers 1. The uppermost (in the drawings) connecting element 5e is conventionally removed to show the internal details of pincers 1. In this embodiment, there is no fixed handle 3.

As shown in FIG. 12, the jaw assemblies 2a, 2b are opened by applying an axial force F to the support member 3a to withdraw the fixed jaw assembly 2a from the movable jaw assembly 2b. The axial force F acts against the bias force of the elastic element 8, which is held between the respective struts 9, mounted on the nodes 2A, 2b of the jaws. When the axial force F is removed, the elastic element 8 attracts the jaw nodes 2a, 2b to each other to gently clamp the clamped part 11a between the jaw nodes.

Turning now to FIG. 13, where the force F applies a torque to the rotary handle 4, so that the cam 4a on the rotary handle acts on the second clamping surface 3c through the sliding shoe 17. This causes the movable jaw assembly 2b to pivot on the cam surface 2c to provide additional clamping to the part 11a.

The options shown in FIGS. 5-8 comprise a fixed jaw assembly 2a that is connected to the fixed handle 3 via an elongated support member 3, and a movable jaw assembly 2b that is connected through one or more connecting elements 5e to the rotary handle 4, so that it can slide and rotate relative to the fixed jaw assembly 2a. The support member 3 is an elongated shaft with parallel opposite facing surfaces 3b, 3c, however, as shown in FIG. 4, the support member may taper toward the fixed jaw assembly. With the rotary handle 4 in the open position, the movable jaw assembly 2b and the rotary handle 4 can slide freely along the support member 3a. An elongated groove 3d is provided in the support element 3, into which an elastic element is introduced in the form of a tension spring 8, one end of which is connected to the movable jaw assembly 2b using a sliding finger 7, and the other end is connected to the fixed jaw assembly 2a using the strut 9a. The tension spring 8 causes the two jaw assemblies 2a, 2b to move towards each other in the locked position. To open the jaw nodes 2a, 2b, the rotary handle 4 is manually retracted from the fixed handle 3 and set in motion along the elongated shaft 3a to introduce the clamped part 11 between the jaw nodes 2a, 2b. Releasing the rotary knob 4 allows the spring 8 to close the jaw assemblies 2a, 2b on the clamped part 11. Manual movement of the rotary knob 4 towards the fixed knob 3 brings the cam 4a on the rotary knob into contact with the second clamping surface 3c on the support member 3a to induce the knot 2b the movable jaw rotate on the cam surface 2c of the movable jaw assembly 2b with respect to the first clamping surface 3b. The rotary handle 4 has a cam locking portion 2d that can be engaged with the support member 3 at a point located above the cam surface 2c (i.e. closer to the fixed jaw assembly 2a). The degree of clamping between the jaw assemblies 2a, 2b and the clamping part 11 increases when the cam 4a rotates relative to the second clamping surface 3c, which causes the movable jaw assembly 2b to rotate in the direction of the fixed jaw assembly until the locking portion 2d contacts the first clamping surface 3b. Provided that the proportional cam 4a is used on the rotary handle 4 and when sufficient force is applied to it by turning the rotary handle 4 in the direction of the fixed handle 3, the clamped part 11 will be firmly gripped between the jaw assemblies 2a, 2b. The clamping degree of the clamped part 11 is directly proportional to the clamping angle Ga or the rotation angle of the movable jaw 2b on the cam surface 2c, until the locking portion 2d is pressed against the first clamping surface 3b. When applied, this can lead to the appearance of additional force acting externally on the nodes 2A, 2b of the jaws. This force depends on the geometry of the movable jaw assembly 2b, the cam surface 2c, the locking portion 2d, the cam 4a, and the locking portion 4b, and will accordingly increase the clamping action on the clamping surfaces 3b, 3c of the support member 3a. With the appropriate proportions of the handles 3, 4, nodes 2a, 2b of the jaws and cams 2c, 4a, the ratio of the shoulders of the lever formed by the handles and jaws is more than 12: 1.

Pliers 1 can be controlled manually with only one rotary knob 4. The gripping of the clamped part 11 can be increased by manually increasing the force F applied between the rotary and stationary knobs 3, 4. Release (cancellation) of the gripping function can be carried out by changing the direction the movement of the rotary handle 4 (that is, due to its movement in the direction of removal from the stationary handle 3), until the gripping force of the jaws of the clamped part 11 by nodes 2a, 2b becomes approximately equal to the force of the tension spring 8. This allows you to change the position of the pliers on the clamped part, similar to a ratchet wrench.

An additional locking function can be introduced into the tongs 1 by using a generally flat locking portion or sections 4b next to the cam 4a on the rotary handle 4, so that the movement of the cam 4a behind the second clamping surface 3c engages the locking portion or sections 4b with the clamping surface . Provided that the locking portion 4b engages with the second clamping surface 3c behind the point corresponding to the right angle from the clamping surface 3c through the center point of the pivot pin 6 (cam blocking distance D1), the jaw units 2a, 2b will remain locked on the clamped part 11 until the manual lever 4 is retracted from the stationary handle 3.

In some embodiments, to minimize the total size of the pincers 1, the layout of the handles 3, 4 is reversed, which causes the rotary handle cam 4a to act on the outer clamping surface 3c and possibly creates a partial reduction in the gripping of the jaws of the clamped part 11 by nodes 2a, 2b To solve this potential problem, a slip shoe 17 may be provided. The slip shoe 17 is held inside the holes in the connecting elements 5e to ensure its correct position between the cam 4a of the rotary handle and the second clamping surface 3c. In use, the cam 4a of the rotary handle will now properly slide over the smooth surface of the slip shoe 17.

The embodiment shown in FIGS. 9-11 comprises a pivot link 12 inserted between the fixed and movable handles 3, 4. An elastic member 8 pulls the pivot link 12 to a position in which its movable end and associated pivot pin 12a are at the end groove 3e in the fixed handle, which (the end) is the closest to the nodes of the jaws. This holds the jaws in the open position shown in FIG. 9. The initial rotation of the handles 3, 4 from the position shown in Fig. 9 leads to the rotation of the rotary handle 4 relative to the rotary link 12 and the pivot pin 12a and to the quick closure of the jaw nodes 2a, 2b on the clamped part 11, until the jaw nodes 2a, 2b will abut against the clamped part 11. Continuing the movement of the rotary handle 4 forces the movable end of the rotary link 12 and the associated pivot pin 12b along the groove 3e, overcoming the resistance of the elastic element 8. This allows the rotary handle 4 to make an additional rotation the mouth in the direction of the fixed handle 3. The movement of the rotary handle 4 in the direction of the fixed handle 3 causes the cam 4a to act on the second clamping surface 3c. The movable jaw assembly 2b then rotates on the cam surface 2c, further clamping the jaw assemblies 2a, 2b on the clamped part 11 and provides sufficient gripping of the clamped part before starting to work with the clamped part.

As shown in FIGS. 12 and 13, a fixed handle 3 is not necessary, provided that the elastic element 8 has sufficient elasticity to close the jaw assemblies 2a, 2b on the clamped part 11 during the initial operation of the rotary handle 4, until the cam 4a of the rotary handle will not have sufficient grip on the second clamping surface 3c to allow the movable jaw assembly 2b to pivot on the cam surface 2c.

The geometric proportions of the ticks 1 can be selected in accordance with various applications and various required gripping forces.

It should be borne in mind that the known hand tools for gripping are designed so that they are rigid and durable, and, in particular, the nodes of the sponges are not designed with the possibility of bending in the direction of removal from the clamped part. By using the deliberate loosening of one or both jaw assemblies, which actually contributes to limited bending in the direction of removal from the clamped part, and therefore in the direction of removal from the other jaw assembly, it is possible to provide a complete locking function of the tool, even when the tool is clamped on a hard and rigid clamped part. In this way, a reliable clamping action can be provided.

It should be borne in mind that each sponge assembly that is provided with a bending assistance section must be made of a material (typically steel) that is resilient enough to bend without permanent (permanent) deformation or other damage.

In accordance with embodiments of the invention, a set of tongs is provided for the operation of rotating fasteners, pipes, etc., and in particular for working with fittings for sanitary work. The pliers mainly allow the locking function. The locking function can advantageously be used to provide a clamping action of the clamping type in a cam chuck, which can be used to lock or clamp various materials, parts of various shapes or fasteners with locking.

It should be borne in mind that the gripping mechanism in accordance with the present invention is not limited only to the pliers described in the various options discussed here. For example, the present invention can be successfully applied to the clamping and locking mechanism of the clamps to unite the boards used in carpentry.

Claims (25)

1. Hand-held gripping tool comprising a first jaw assembly having an engagement portion with a clamped part, a second jaw assembly having an engagement portion with a clampable part and movable with respect to said first jaw assembly, providing a variable size space for receiving a clampable part between said engagement portions with a clamped part, and a handle for applying force to the node of the second sponge, and the node of the second sponge is made with the possibility of entering into engagement with the reaction surface, providing when applying in response to the application of force by means of the indicated handle, the clamping of its engagement section with the clamped part to the clamped part inserted into the space for receiving the clamped part, and which comprises an extension section extending from the specified engagement section with the clamped part, the handle shoulder being connected to the specified extension section at the junction, and the specified extension section has a bending assistance section located between the specified section of engagement with the clamped part and the specified place is connected I, wherein bending assist portion is configured to promote limited bending elongation portion in a direction away from said first jaw assembly in response to the reaction force that is generated due to engaging with said workpiece clamped between nodes of the first and second jaws. 2. The tool of claim 1, wherein the bending assistance portion comprises a section that is curved in the transverse direction with respect to the length of the extension portion. 3. The tool according to claim 2, in which the extension section contains at least one flat element, and the curved section has a bend in the plane of the extension section. 4. The tool according to claim 2, in which the curved section has a curvature in the direction of the node of the first sponge. 5. The tool according to claim 1, in which the plot to facilitate bending is located next to the reaction surface. 6. The tool according to claim 1, in which the elongation section contains two elongated elements located offset with each other, each elongated element contains a plot to facilitate bending. 7. The tool according to claim 1, which further comprises a support element for the second sponge assembly, said support element being laterally relative to the first sponge assembly, and the second sponge assembly being slidable relative to the first sponge assembly along the specified support element to resize space for receiving the clamped part. 8. The tool according to claim 7, in which the support element forms a specified reaction surface. 9. The tool according to claim 7, in which the support element comprises a first side surface facing toward the space for receiving the clamped part, and a second side surface located opposite and offset from the specified first side surface, and the gap between the first and second side surfaces is reduced as they approach the node of the first sponge. 10. The tool of claim 8, which further comprises a cam device connected to the rotary handle and causing the second jaw assembly to engage with the reaction surface. 11. The tool according to claim 1, which further comprises an automatic locking device for locking the node of the second sponge, providing a fixation of the size of the space for receiving the clamped part, and the specified automatic locking device contains a locking element made with the possibility of moving to the output inoperative position. 12. The tool according to claim 11, which further comprises a biasing device configured to bias the locking element into position. 13. The tool according to claim 11, which further comprises a fixed handle connected to the node of the first sponge, and a pivoting link rotatably connected from each of the handles and provided with a finger made to slide into a groove formed in one of the handles. 14. The tool according to item 13, in which the locking element is made with the possibility of entering into engagement with the specified rotary link to lock the node of the second sponge. 15. The tool according to 14, in which the locking element is provided with formations for mutual engagement with the formations provided on the specified rotary link. 16. A manual gripping tool comprising a first jaw assembly, a second jaw assembly, a first cam connected to a first jaw assembly, a rotary handle for applying labor to the first jaw assembly, and a second cam connected to the rotary handle, the first and second jaw assemblies made with the possibility of interaction for the formation of a space of variable size for receiving the clamped part, and the first and second cams are made with the possibility of actuation in response to the application of labor and prompting these nodes of the first and second the jaw to clamp the clamped part, which is located in the specified space of variable size, and at least one of the nodes of the first and second jaws contains a bending assistance section that facilitates the bending of the jaw assembly in the direction of removal from the specified space of variable size, in response to the reaction force created with the help of a part sandwiched between the nodes of the first and second jaws in a space of variable size. 17. The tool according to clause 16, in which the node of the first jaw contains a connecting section between the first cam and the rotary handle, and the specified section to facilitate bending is formed using this connecting section, while the section of assistance to bending forms a fulcrum relative to which the node of the first sponge can bend in the direction away from the space of variable size. 18. The tool according to clause 16 or 17, in which the node of the second jaw contains the specified plot to facilitate bending, and the plot to facilitate bending contains a recess provided on the outer side surface of the node of the second sponge facing in the direction of removal from the space of variable size. 19. A gripping hand tool comprising a first jaw block, a second jaw block cooperating with a first jaw block to form a variable-sized space for receiving a clamped part, a support means on which the first sponge block slides to resize a space for receiving a clamped part, and a pivoting lever means, and both the first jaw block and the pivoting lever means, are provided with an engaging means for engaging with corresponding parts on said supporting means, when m the pivoting lever means is arranged to provide a pivoting movement in one direction forcing the first jaw block to move in the direction of the clamped part, which is located in the space for receiving the clamped part, at least in contact with the blocks of the first and second jaws to clamp the part, and the first block the jaw is made with the possibility of limited movement of the bend in the direction away from the space for receiving the clamped part in response to the reaction force created by the part clamped between the nodes of the per oh and second jaws in a space of variable size. 20. The tool according to claim 19, in which the gearing means and the corresponding parts on the support means are arranged to provide a gradually increasing gripping force in the entire range of the rotation movement. 21. The tool according to claim 19 or 20, in which at least one means of engagement is made with the possibility of interaction with the corresponding part on the support means to ensure when the movement of rotation in one direction outside the specified range of the specified movement lock block the first jaw in a part inserted into the space for receiving the clamped part. 22. The tool according to claim 19, which further comprises an automatic locking device for locking the first jaw block regardless of engagement between the engaging means and corresponding parts on the support means when the lever means is moved in the indicated one direction beyond the locking position. 23. The tool according to item 22, in which the automatic locking device is made with the possibility of selective installation in the inoperative position. 24. The tool according to claim 19, in which the block of the first sponge contains corrugations for the implementation of the specified motion of the bend. 25. The tool according to paragraph 24, in which the corrugations contain at least one arc formed on the block of the first sponge, and the specified arc has a curvature in the plane of the block of the first sponge, directed towards the space for receiving the clamped part.

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