The invention relates to a toggle clamp, comprising a base, a clamping arm articulated to the base for pivotal movement about a first pivot axis, a handle articulated to the clamping arm or the base for pivotal movement about a second pivot axis, a bridge element articulated to the handle or the clamping arm for pivotal movement about a third pivot axis, a first wedge element having a first wedge surface, said first wedge element being linearly guided on a guide, and a second wedge element having a second wedge surface facing towards the first wedge surface, said second wedge element being adapted to the first wedge element and being linearly guided, wherein in a first positional range of the handle, the first wedge surface and the second wedge surface are spaced apart from one another and wherein in a second positional range of the handle, the second wedge surface is supported on the first wedge surface and a displacement of the first wedge element drives a displacement of the second wedge element.
Toggle clamps are used for example to clamp workpieces in place on a machine table. The displacement capability of the first wedge element allows adjustment to accommodate different heights of workpieces to be clamped within a certain range.
U.S. Pat. No. 4,407,493 disclose a toggle clamp which is self-adjusting (“self-adjusting toggle clamp”).
Further toggle clamps are known from US 2010/0148414 A1 or WO 2010/045504 A1.
U.S. Pat. No. 2,350,034 discloses a toggle clamp having a base and an L-shaped clamping arm made of a U-shaped strap having its free ends pivotally connected to the base. The connection is at a point where a pivot bearing passes laterally through the strap ends. Furthermore, there is provided a clamping element which is located at the other end of the clamping arm. A handle has one of its ends pivotally connected to a point located in the bend of the L of the clamping arm. A link has one end pivotally connected to the base and the other end pivotally connected to the handle at a point between the pivotal connection of the handle with the clamping arm and the pivotal connection between the link and the base. When the corresponding parts are in a clamping position, the pivotal connections between one end of the link and the base, the handle with the clamping arm, and the handle with the other end of the link are aligned in one line. The pivotal connection between the handle and the other end of the link is intermediate the other of the pivotal connections. The base has provided thereon means for limiting the movement of the link and the clamping arm.
Further clamping tools are disclosed in U.S. Pat. No. 3,116,656, U.S. Pat. No. 2,531,285, U.S. Pat. No. 3,600,986 and U.S. Pat. No. 2,751,801.
In accordance with an exemplary embodiment of the invention, there is provided a toggle clamp which affords a wide range of variation with simplicity of construction.
In accordance with an exemplary embodiment of the invention, the bridge element is connected to the first wedge element and is articulated to the first wedge element for pivotal movement about a fourth pivot axis.
In the solution in accordance with the invention, the bridge element is permanently connected to the first wedge element by a joint connection for the articulating action. The number of components can thereby be kept low, and therefore the corresponding toggle clamp is easy to manufacture. There results a wide range of variation for the clampability of workpieces in terms of workpiece height above a support upon which the toggle clamp is set. This affords a simple way of adjusting a clamping force.
In particular, the bridge element is of rigid configuration and is in particular formed in a one-piece configuration. This makes the toggle clamp simple to manufacture.
For the same reason, it is advantageous for the bridge element to be of rigid configuration between a joint for articulation to the handle or to the clamping arm and a joint for articulation to the first wedge element. The bridge element then merely represents a fixed bridge element.
Advantageously, the first pivot axis, the second pivot axis, the third pivot axis and the fourth pivot axis are oriented parallel to one another. A toggle clamp can thereby be realized in a simple manner.
It is particularly advantageous for an adjustment device to be provided which acts on the second wedge element and which provides a capability of adjusting a position of the second wedge element in which the first wedge element acts on the second wedge element for driving it. The adjustment device provides a capability of adjusting at what pivotal position of the handle the first wedge element starts driving the second wedge element. The locking force of the toggle clamp for a workpiece is thereby capable of being adjusted.
It is particularly advantageous for the adjustment device to be arranged on the bridge element and, in particular, to be held on the bridge element. The bridge element then has the same pivot point as the bridge element. This results in a simple construction of the toggle clamp. The adjustment device can be easily accessed by use of a tool, such as a screwdriver, or without the use of tools because there is enough space available for this action. It is easily implemented that a clamping force is capable of being adjusted in a defined manner over a large angular range for the clamping arm relative to a support, and in particular over the entire angular range. Once adjusted, the clamping force is at least approximately the same for different workpiece heights. The toggle clamp is thereby easy to use.
In an exemplary embodiment, the adjustment device comprises an operative element located on the bridge element for pivotal movement about a fifth pivot axis. It is then possible for the locking force to be adjusted by a relative angular position of the operative element relative to the bridge element.
In particular, the fifth pivot axis is parallel to the fourth pivot axis. This makes for a simple construction.
In an advantageous embodiment, the operative element has located thereon an adjustment element by which an angular position of the operative element relative to the bridge element is capable of being fixably adjusted. In particular, the adjustment element is a spacer element which fixes a distance to the bridge element at or near an end of the operative element, thereby fixing the angular position of the operative element relative to the bridge element.
In an embodiment that is advantageous in terms of manufacturability, the adjustment element is a screw which is guided in a thread on the operative element and which is in particular supported at one end thereof on the bridge element. This gives simplicity of construction. Threadedly guiding the screw provides a simple way of fixably adjusting the relative position of the operative element relative to the bridge element.
Provision may be made for the operative element to be supported on the first wedge element in at least a portion of a range of pivotal motion of the operative element. This results in increased stability.
It is advantageous for the operative element to be of rounded configuration in an area in which it is capable of acting on the second wedge element. The rounding is defined. This provides an effective way of fixing the starting position of the second wedge element within a predetermined pivoting range and hence, in turn, of fixing the position at which the first wedge element can start driving the second wedge element. This in turn fixes the locking force. With appropriate configuration, an angle-independent clamping force can be at least approximately adjusted.
It is advantageous for a spring device to be provided which acts on the second wedge element, wherein a spring force of the spring device tends to urge the second wedge element in a direction towards the bridge element. The spring device then provides for the second wedge element to be able to be in contact against a contact surface of an adjustment device when the first wedge element does not yet contact the second wedge element.
In one embodiment, the guide is arranged on the base. This makes for a simple construction.
In an alternative embodiment, the guide is arranged on the handle. This makes for a compact construction.
In an embodiment, the handle is pivotally articulated to the base and the second wedge element has a recess in which is positioned a joint or joint part for the second pivot axis. The handle can thereby be articulated to the base at a point which is spaced at a height distance from an articulation of a clamping arm to the base. This provides a simple way of realizing for example a horizontal clamp in which the guide is arranged on the handle.
In particular, the recess is configured in the form of an elongated hole recess which enables a displacement capability of the second wedge element, and the elongated hole recess is in particular configured as a guide for the second wedge element. This does not interfere with the displacement capability of the second wedge element. The corresponding joint can then at the same time be used as a linear guide for the second wedge element.
A toggle clamp constructed in accordance with the invention can be configured as a horizontal clamp in which clamping of a workpiece by the clamping arm is capable of being effected by pivoting the handle in a direction towards the base.
In particular, the clamping arm is then articulated to the base, the handle is articulated to the clamping arm and the bridge element is articulated to the handle.
It is advantageous for the bridge element to be oriented at least approximately parallel to the clamping arm when at a toggle lever dead centre. A horizontal clamp can thereby be implemented in a simple manner.
Provision may also be made for the toggle clamp to be configured as a vertical clamp in which clamping of a workpiece by the clamping arm is capable of being effected by pivoting the handle in a direction away from the base.
In an embodiment, the clamping arm is articulated to the base, the bridge element is articulated to the clamping arm and the handle is articulated to the base. In particular, the point of articulation of the handle to the base in relation to the position of the point of articulation of the clamping arm to the base determines whether the clamp is of the horizontal or the vertical type.
It is advantageous for the bridge element to be oriented at least approximately parallel to the handle when at a toggle lever dead centre.
In an embodiment, the clamping arm has arranged thereon a contact element for a workpiece, in particular wherein a distance of the contact element to the clamping arm is capable of being fixably adjusted. In particular, the contact element comprises a pressure piece for contact against the workpiece. When a distance of the contact element from the clamping arm is capable of being fixably adjusted, then this will result in a high capability for adjustment. For example, the contact element is also held pivotally to the clamping arm in order to be able to compensate for, in particular, an inclined position of the clamping arm relative to a workpiece.
The following description of preferred embodiments serves in conjunction with the drawings to explain the invention in greater detail.
A first exemplary embodiment of a toggle clamp constructed in accordance with the invention, shown in
A clamping arm 20 is articulated to the base 12 via a first joint 16 which defines a first pivot axis 18. The first pivot axis is oriented perpendicularly to the drawing plane in
The clamping arm 20 is of angled configuration having a first region 22 and a region 24 oriented transversely to the first region 22. The first joint 16 is positioned in the vicinity of an end of the first region 22.
Located at the second region 24, in the vicinity of an end 26 thereof, is a contact element 28 which is in particular configured as a pressure piece. The contact element 28 is supported on a holding ball 30. The contact element 28 has a contact surface 32 for the workpiece 15. The contact element 28 further has a receptacle 32 which is adapted to the holding ball 30. By the holding ball-and-receptacle connection of the contact element 28, the pivotal position of the contact element 28 relative to the clamping arm 20 is variable.
The holding ball 30 is fixed to the second region 24 of the clamping arm 20 via a holding pin 34.
In an embodiment, a distance of the contact element 28 from the clamping arm 20 is capable of being fixably adjusted. To this end, for example, the holding pin 34 is configured, in particular in a portion thereof, as a threaded pin which is guided on a thread of the clamping arm 20.
A handle 40 is articulated to the clamping arm 20 via a second hinge 36 which defines a second pivot axis 38. The second joint 36 is arranged at the first region 22 in the vicinity of an end facing away from the end which has the first joint 16 positioned in its vicinity. In a state in which the base 12 of the toggle clamp 10 is set on the support, the second joint 36 has a distance from the support 14 that is greater than that of the first joint 16.
The handle 40 is of angled configuration having a first region 42 and a second region 44. The first region 42 and the second region 44 have a finite angle 46 therebetween in the range between, for example, 120° and 150°.
Arranged on the handle 40, at an end region thereof, is a grip element 48 which is made of, for example, a plastics material. The grip element 48 has a contact region 52 for contact with a user's hand.
The second pivot axis 38 is parallel to the first pivot axis 18.
The handle 40 has arranged thereon a third joint 54 which defines a third pivot axis 56. The third joint 54 is spaced apart from the first joint 16 and the second joint 36. The third pivot axis 56 is parallel to the first pivot axis 18. A distance of the third joint 54 from the support 14 depends on a pivotal position of the handle 40. A bridge element 57 is articulated to the handle 40 via the third joint 54. In particular, the third joint 54 is located at the second region 44 of the handle in the vicinity of the transition from the first region 42 to the second region 44.
Formed on the base 12 is a guide 58 for a first wedge element 60. In particular, the first wedge element 60 is guided for linear slidable displacement in the guide 58 on the base 12. A direction of displacement 62 thereof is parallel to a guide surface 64 of the base 12. In particular, the guide surface 64 is of planar configuration. Preferably, the guide surface 64 is oriented parallel to the support 14 when the base 12 is set on the support 14. The distance of the first wedge element 60 from the support is the same independent of the position the first wedge element 60 assumes on the guide 58.
The first wedge element 60 has an underside 66 with which the first wedge element 60 is set on the guide surface 64. The underside 66 is oriented parallel to the guide surface 64.
The first wedge element 60 further comprises a first wedge surface 68 which is oriented at an acute angle with respect to the underside 66, said acute angle being in the range between 10° and 20°, for example.
The bridge element 57 is articulated via a fourth joint 70 to the first wedge element 60 and is permanently connected thereto. The fourth joint 70 defines a fourth pivot axis 72 which is parallel to the first pivot axis 18. The articulation of the bridge element 57 to the first wedge element 60 is outside of the confines of the first wedge surface 68.
The bridge element 57 is of rigid configuration. In particular, it is of rigid configuration, i.e. not movable in itself, between the third joint 54 and the fourth joint 70. It is not interrupted by another joint or the like.
The first wedge element 60 has a second wedge element 74 associated with it. The second wedge element 74 is also linearly guided on the base 12, in a direction of displacement 76 that is parallel to the direction of displacement 62. The second wedge element 74 is arranged above the first wedge element 60. A guide 78 of the second wedge element 74 on the base 12 is configured such that the height position of the second wedge element 74 relative to the guide surface 64 does not change. This is achieved for example by a lateral guide (not visible in the chosen views of the figures).
The second wedge element 74 has a second wedge surface 80 which is adapted to the first wedge surface 68 and is parallel thereto. The second wedge element 74 has, at a position opposite the second wedge surface 80, an upper side 82 via which the second wedge element 74 is guided, for example slidably guided, on a corresponding wall 84 of the base 12 opposite the guide surface 64. The upper side 82 is oriented parallel to the underside 66 of the first wedge element 60.
In an exemplary embodiment, the second wedge element 74 is supported on the base 12 via a spring device 86. In particular, the spring device 86 is supported on a rear wall 88 which is located between the wall 84 and the guide surface 64. Furthermore, the spring device 86, which has one or more compression springs, is fixed, or supported, on a side of the second wedge element 74 that faces towards the rear wall 88.
A direction of force 90 of the spring device 86 is directed away from the rear wall 88 and towards the bridge element 57. In particular, the direction of force 90 is oriented at least approximately parallel to the guide surface 64. The spring device 86 tends to urge the second wedge element 74 in a direction towards the bridge element 57.
Arranged intermediate the first wedge element 60 and the second wedge element 74 is an intermediate element 75. This is arranged and configured parallel to the wedge surfaces 68 and 80 and is guided parallel to the guide surface 64 on the base 12. It is guided on the base 12 in such a manner that it is free to move and “float” in a direction of height relative to the base 12. The first wedge element 60 acts on the second wedge element 74 via the intermediate element 75. The intermediate element 75 absorbs transverse forces and transfers these to the base 12. Transverse movement capability of the wedge elements 60 and 74 is thereby precluded.
The second wedge element 74 has associated with it an adjustment device 92 which provides the capability of adjusting the position into which the second wedge element 74 is capable of being urged by the spring device 86 in a direction towards the bridge element 57. A clamping force is adjustable by the adjustment device 92.
The adjustment device 92 comprises an operative element 94. The operative element 94 has, on a side thereof opposite that side on which the spring device 86 is supported, a contact surface 96 for the second wedge element 74. In particular, the operative element 94 is of rounded configuration in the area of the contact surface 96 thereof.
The operative element 94 is pivotally located on the bridge element 57 via a corresponding holder 98. To this end, a fifth joint 100 is provided which defines a fifth pivot axis 102. The fifth pivot axis 102 is parallel to the first pivot axis 18.
The fifth joint 100 divides the operative element 94 in a first region and a second region. The first region has the contact surface 96 formed thereon. The second region has an adjusting element 104 located thereon. The adjusting element 104 is in particular a screw which is guided via an external thread thereof on an internal thread of the operative element 94. The adjusting element 104 has a region 106 which projects beyond the operative element 94 in a direction towards the bridge element 57. A length of this region 106 towards the bridge element 57 is adjustable. This is indicated in
The adjusting element 104 is positioned above the wall 84 so that the adjusting element 104 is capable of having a suitable tool, such as a screwdriver, acting upon it for its adjustment.
The toggle clamp 10 is configured as a horizontal clamp. A toggle lever is realized via the joints 16, 36, 54 and 70. The workpiece 15 can be clamped to the support 14 by pivoting the handle 40 in a direction towards the base 12. This direction of motion is indicated in
The toggle clamp 10 is configured and is in particular dimensioned such that in a first positional range of the handle 40 in which no clamping has yet been applied, wherein a position of the handle 40 within the aforesaid first positional range is shown in
In the position illustrated in
The displacement distance travelled by the first wedge element 60 until it reaches the aforesaid position defines the extent of the self-adjustment capability of the toggle clamp 10.
Proceeding from the aforesaid position for a special angle 114* (
The clamping arm 20 securely presses on the workpiece 15 via the contact element 28 and clamps it against the support.
In this condition, the workpiece 15 is securely and firmly clamped in place between the contact element 28 on the clamping arm 20 and the support 14.
The clamping force (the toggle lever force) is, in principle, capable of being adjusted by the adjustment device 92.
The bridge element 57, configured as a rigid element, is directly and permanently connected to the first wedge element 60 and is directly articulated to the latter via the fourth joint 70. The result is simplicity in construction with a wide range of variation for clamping height (workpiece height).
The adjustment device 92 including the adjusting element 104 is arranged on the bridge element 57. In particular, the operative element 94 is pivotally arranged on the bridge element 57. This provides a simple way of adjusting the corresponding clamping force (toggle lever force) by the position of the second wedge element 74 in the first positional range of the handle 40.
The adjusting element 104 is easily accessed by use of a standard tool, such as a screwdriver, in order to adjust the corresponding force.
The displacement capability of the first wedge element 60 allows compensating for different workpiece heights to a certain extent; a point of support of the clamping arm 20 is variable. The toggle clamp 10 is thereby self-adjusting (“self-adjusting toggle clamp”).
A second exemplary embodiment of a toggle clamp constructed in accordance with the invention, illustrated in
A handle 130 is pivotally articulated to the base 122 via a second joint 128. The second joint 128 is spaced at a height distance from the first joint 124.
The handle has located thereon a guide 132 for a first wedge element 134 and a second wedge element 136.
A bridge element 138 is pivotally articulated to the clamping arm 126 via a third joint 140. The bridge element 138 is pivotally articulated via a fourth joint 142 to the first wedge element 134 and is permanently connected thereto.
The first wedge element 134 is capable of being displaced parallel to the handle 130 via the guide 132. The second wedge element 136 is positioned above the first wedge element 134. It is urged in a direction towards the bridge element 138 via a spring device 144.
The first joint 124, the second joint 128, the third joint 140 and the fourth joint 142 form a toggle lever.
Located on the bridge element 138 is an adjustment device which is, in principle, of identical configuration as that of the adjustment device 92. Therefore, the same reference characters are used as those for the adjustment device 92. An operative element 94 acts upon the second wedge element 136 via a contact surface 96.
The second wedge element 136 has a recess 146 in the form of, for example, an elongated hole recess. The recess 146 is formed as a through-recess. The through-direction of this recess 146 is perpendicular to the drawing plane of
In order to clamp a workpiece to the support 14, the handle 130 is pivoted in a direction 148 towards the base. The toggle clamp 120 is also a horizontal clamp. By the aforesaid pivoting action, the bridge element 138 pushes the first wedge element 134 in a direction towards a grip element 150 which is located on the handle 130.
Shown in
The handle 130, including the guide 132, and the bridge element 138 are at a certain angle 152 to each other. Pivoting the handle 130 towards the base 122 causes said angle 152 to be reduced. As shown in
A toggle lever dead centre position is at least approximately reached when the angle 152 is 0°, i.e. when the handle 130 and the bridge element 138 are oriented parallel to each other or piercing points of pivot axes of the second joint 128, the third joint 140 and the fourth joint 142 are on one line with each other.
Again, the adjustment device 92 allows the clamping force (toggle lever force) to be adjusted.
In the toggle clamp 120, the bridge element 138 is also of rigid configuration. It is permanently pivotally connected to the first wedge element 134 and is articulated to the latter.
A third exemplary embodiment of a toggle clamp constructed in accordance with the invention, illustrated in
The clamping arm 167 has, at a position above the first joint 164, a bridge element 178 pivotally articulated thereto via a third joint 174 having a third pivot axis 176.
Guided for linear displacement on the handle 172, on a guide 180, is a first wedge element 182. The bridge element 178 is permanently pivotally articulated to the first wedge element 182 via a fourth joint 184 having a fourth pivot axis 186.
The first wedge element 182 has associated with it a second wedge element 188 which is likewise linearly displaceable on the handle 172. Furthermore, the bridge element 178 has positioned thereon an adjustment device corresponding to the adjustment device 92. Therefore, the same reference character is used as in the first exemplary embodiment and in the second exemplary embodiment.
The toggle clamp 160 is configured as a vertical clamp. Clamping a workpiece to a support is achieved when the handle 172 is pivoted in a direction 190 away from the base 162.
The guide 180 and the bridge element 178 have an angle 192 therebetween. When the handle 172 is pivoted in the direction 190, the angle 192 is reduced (cf.
The second wedge element 188 is supported on a rear wall 196 via a spring device 194.
Further pivoting of the handle 172 then causes the angle 192 to be reduced. At angle 192* (
A toggle lever dead centre position is reached when the angle 192 is 0°, i.e. when the guide 180 of the handle 172 and the bridge element 178 are at least approximately parallel to each other or piercing points of the pivot axes 170, 176 and 186 are on one line with each other.
In the toggle clamps 10, 120, 160 constructed in accordance with the invention, a corresponding bridge element 57, 138, 178 is of rigid configuration and is directly and permanently articulated to the first wedge element 60, 134, 182, i.e. a permanent pivotal connection exists between the first wedge element 60, 134, 182 and the bridge element 57, 138, 178. The adjustment device 92 is positioned on the corresponding bridge element 57, 138, 178 and therefore its pivot point is the same as that of the corresponding bridge element 57, 138, 178.
This results in a simple construction with a wide range of variation for the clamping action, i.e. with a wide range of variation for the height of workpieces capable of being clamped.
The clamping force (toggle lever force) can be adjusted via the adjustment device 92 in a simple manner. In particular, access to the adjusting element 104 can be realized in a simple manner. The clamping force can be at least approximately constantly fixed over a wide angular range/height range of workpieces.
10 toggle clamp (first exemplary embodiment)
12 base
14 support
16 first joint
18 first pivot axis
20 clamping arm
22 first region
24 second region
26 end
28 contact element
30 holding ball
32 receptacle
34 holding pin
36 second joint
38 second pivot axis
40 handle
42 first region
44 second region
46 angle
48 grip element
52 contact region
54 third joint
56 third pivot axis
57 bridge element
58 guide
60 first wedge element
62 direction of displacement
64 guide surface
66 underside
68 first wedge surface
70 fourth joint
72 fourth pivot axis
74 second wedge element
75 intermediate element
76 direction of displacement
78 guide
80 second wedge surface
82 upper side
84 wall
86 spring device
88 rear wall
90 direction of force
92 adjustment device
94 operative element
96 contact surface
98 holder
100 fifth joint
102 fifth pivot axis
104 adjusting element
106 region
108 double-headed arrow
110 direction of motion
112 air gap
114 angle
116 direction of longitudinal extent
120 toggle clamp (second exemplary embodiment)
122 base
124 first joint
126 clamping arm
128 second joint
130 handle
132 guide
134 first wedge element
136 second wedge element
137 intermediate element
138 bridge element
140 third joint
142 fourth joint
144 spring device
146 recess
148 direction
150 grip element
152 angle
160 toggle clamp (third exemplary embodiment)
162 base
164 first joint
166 first pivot axis
167 clamping arm
168 second joint
170 second pivot axis
172 handle
174 third joint
176 third pivot axis
178 bridge element
180 guide
182 first wedge element
183 intermediate element
184 fourth joint
186 fourth pivot axis
188 second wedge element
190 direction
192 angle
194 spring device
196 rear wall
Number | Date | Country | Kind |
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10 2013 104 413 | Apr 2013 | DE | national |
This application is a continuation of international application number PCT/EP2014/058651 filed on Apr. 29, 2014 and claims the benefit of German application No. 10 2013 104 413.1 filed on Apr. 30, 2013, which are incorporated herein by reference in their entirety and for all purposes.
Number | Date | Country | |
---|---|---|---|
Parent | PCT/EP2014/058651 | Apr 2014 | US |
Child | 14875796 | US |