The application is the U.S. National Stage of International Application Number PCT/EP2014/068693, filed on Sep. 3, 2014, which claims the benefit of European Patent Application Number 13185168.5, filed on Sep. 19, 2013, which are each incorporated by reference.
The invention concerns a fastener driving tool.
Fastener driving tools with various drive means are known from the prior art, including tools operated with external compressed air, tools operated with a combustible gas, or tools that have a mechanical spring energy accumulator.
DE 10 2005 000 107 A1, in the embodiment example shown in
It is the problem of the invention to specify a fastener driving tool that exhibits good acceleration of an energy transmission element for a given tool size.
For an above-mentioned fastener driving tool, this problem is solved in accordance with the claimed invention. Through the provision of a variable wall segment in combination with a mechanical energy accumulator, a more uniform accelerating force can be exerted on the energy transmission element. Besides the energy elastically stored in the gas, the energy of an additional energy accumulator is utilized for this, where the energy supplied from the additional energy accumulator likewise acts on the piston via the gas pressure in the gas compartment.
A mechanical energy accumulator in the sense of the invention is understood to be any structural element that can accept mechanical energy and intermediately store it. For example, it can be a gas spring or, preferably, an elastically deformable solid body. An elastically deformable solid body is understood to be, among others, coil springs, helical springs, plate springs, torsion bar springs, elastic bands made of an elastomer, or the like.
A fastening element in the meaning of the invention is understood to be any drivable nail, bolt, or even a screw.
In preferred embodiments, the fastener propellant gas is air, in particular ambient air. However, it can also be gases like air, nitrogen, or carbon dioxide from a pressurized reservoir, or also reaction gases from combustion.
In a generally preferred embodiment of the invention, the energy accumulator is an elastically deformable solid body. Such energy accumulators generate lower heat losses and with regard to their spring constant, can readily be combined with the gas compartment.
In a first preferred embodiment of the invention, the energy accumulator comprises an elastic membrane, where the membrane forms the additional wall segment. Through an expansion of the gas compartment volume, the membrane becomes stretched against its elastic restoring force and thus is used as an energy accumulator. In a fastener driving operation, the membrane initially contracts and, at least in a first segment of the motion of the piston, causes the gas pressure acting on the piston to even out.
It is provided in the case of an alternative or even supplemental embodiment that the energy accumulator comprises a piston as additional wall segment and a spring, where the piston is braced against the spring. In this case the advantages of mechanical springs, in particular metal springs, with regard to their low space requirement and the high potential spring constants can be utilized.
In a preferred further development, the piston can be moved in the same direction of motion as the piston of the energy transmission element. This allows a particularly simple design of the remaining housing wall of the gas compartment, for example as a simple or stepped cylinder.
Generally advantageously, the propellant gas is transported into the gas compartment by means of a compressor, which is preferably integrated in the housing. This allows independence from external gas sources such as a compressed air line. Preferably, the compressor in this case comprises an electric motor, where especially preferably the electric motor is powered at least optionally by a battery as its energy source. This enables a cordless tool, and at the same time the high energy densities of modern batteries can be utilized.
Other features and advantages of the invention follow from the embodiment examples and the dependent claims. Below a number of preferred embodiment examples of the invention are described and explained in more detail by means of the appended drawings.
The fastener driving tool from
The energy transmission element 2 comprises a driving element 2a, in the form of an essentially cylindrical ram. A cushioning stop 4 for the energy transmission element 2 is disposed in a front region of the fastener driving tool.
Fasteners are held in a magazine 5. A fastening element is transported each time by a feed mechanism (not shown) into a compartment, from which it is accelerated by the effect of the driving element 2a and is driven into a workpiece (not shown) through a mouthpiece.
The driving element 2a is connected to a piston 2b of the energy transmission element 2, and the piston 2b is guided in a cylinder 6.
The gas compartment 7 can be filled with a propellant gas, in this case compressed air, at an excess pressure with respect to the ambient pressure. The gas compartment 7 is surrounded by a solid wall segment, which also comprises a pressure-side part of cylinder 6, the movable piston 2b as a first variable wall segment, and an elastic membrane 8 as a second variable wall segment.
The elastic membrane 8 expands, according to the pressure or degree of filling of the gas compartment 7 against its inherent material stress. Through this, it forms a mechanical energy accumulator, in which energy is stored in addition to the energy in the gas, which is under pressure. To avoid overstretching of the membrane, it is surrounded by a solid housing wall 1a, against which it can lie at the maximum expansion.
Filling of the gas compartment 7 takes place by means of compressor 9, which is only shown schematically in the figures. The compressor 9 is driven by an electric motor, for example a spinning electric motor in combination with an oscillating mechanism. The energy source of the electric motor is a battery 10 provided on the housing 1.
For examples of detail and design of the compressor and its drive and also other components of the fastener driving tool such as a trigger device and a return spring for the energy transmission element, one is referred in particular to DE 10 2005 000 107 A1.
The invention now operates as follows:
In the indicated starting position of piston 2b, ambient air is pumped into the gas compartment 7 by means of the compressor until a specific pressure is reached. This can in particular be a maximum pressure of the compressor.
As this happens, the membrane 8 is converted from a relaxed state (dashed line in
In this state the tool can be triggered when needed, which takes place through an electromechanical release of the energy transmission element 2, which was previously locked in place. After its release, the piston 2b is accelerated in the forward direction by the applied pressure. Since the membrane relaxes at first, the gas pressure is only reduced a little in at least a first segment of motion.
After driving in the fastener, the energy transmission element 2 is reset to the starting position by a return spring (not shown) and locked in place. This is followed by refilling of the gas compartment 7 by the compressor 9.
In the second embodiment example of the invention shown in
Piston 11 is guided gastight along cylinder 12, where cylinder 12 is freely connected to the atmosphere on the outer side of piston 11. Piston 11 is additionally braced against a plurality of springs 13, which in this case are coil springs made of metal. In embodiment examples that are not shown, they are torsion bar springs, helical springs, or leaf springs of metal or plastic or an elastomer. A plurality of springs 13 is shown schematically, each of which acts as tension spring or pressure spring according to its position with respect to the piston. The springs 13 can be disposed inside and/or outside the gas compartment 7. Space in the tool can be saved with particular efficiency by an at least partial arrangement inside the gas compartment.
The function of the fastener driving tool according to the second embodiment example is analogous to the first embodiment example, with the difference that the springs form the additional mechanical energy accumulator instead of the membrane material. In this case the piston 11 moves against the force of springs 13 when the pressure in the gas compartment arises, so that the gas compartment becomes larger, as in the first embodiment example.
Of course, the individual features of the different embodiment examples can be combined with each other in each case according to requirements.
Number | Date | Country | Kind |
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13185168 | Sep 2013 | EP | regional |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2014/068693 | 9/3/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2015/039865 | 3/26/2015 | WO | A |
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Number | Date | Country | |
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20160207186 A1 | Jul 2016 | US |