1. Field of the Invention
The present invention relates to a combustion-engined setting tool for driving fastening elements such as, e.g., nails, bolts, pins, in a constructional components and which includes a combustion chamber, means arranged in the combustion chamber for generating turbulence of an oxidant-fuel mixture filling the combustion chamber, an ignition unit for igniting the oxidant-fuel mixture, and drive means for a least temporarily driving the turbulence generating means.
2. Description of the Prior Art
In the setting tools described above, a portion of the liquid gas or another vaporable fuel, which is mixed with an oxidant, e.g., environmental air, is combusted in the tool combustion chamber. In order to obtain as high as possible drive-in energy from the combustion process, it is important that the combustion of the gas or gas mixture takes place under turbulent flow conditions. Only a turbulent combustion permits to obtain a necessary drive-in energy from the combustion process, producing a sufficiently rapid pressure increase in the combustion chamber for accelerating the setting piston to a degree necessary for driving a fastening element in. With a laminar combustion, the combustion process and the resulting pressure increase take place so slow that only a fraction of the required mechanical energy can be obtained from the combustion process.
European Patent EP-0 544471B1 discloses a combustion-engined setting tool having a combustion chamber for combusting a mixture of air and fuel gas and in which ventilator means is provided in the combustion chamber for generating turbulence therein. The ventilator means is driven by an electric motor which is supplied with electrical energy from a battery. The ventilator means is actuated by the head switch of the setting tool when the setting tool is pressed against a constructional component. The ignition unit is actuated for igniting the air-fuel mixture in the combustion chamber when an actuation switch is actuated, while the head switch is still closed.
The drawback of the setting tool of the European Patent consist in complicated and costly electronics which actuates and controls the ventilator means and which also actuates ignition. A further drawback consists in that several accumulators are needed, which increases the tool weight.
German Publication DE 199 62 711 A1 discloses a combustion-engined setting tool in which a separation plate with through-openings is arranged in the combustion chamber, dividing the combustion chamber in two chambers. An adjustment device is used for changing the distance between the separation plate and a rear wall that axially limits the combustion chamber, whereby the volumes of the forechamber and the main chamber change. In the forechamber, a first portion of the air-fuel mixture is ignited, with the flame jets penetrating into the main chamber through the openings in the separation plate, creating turbulence in the main chamber and igniting the air-fuel mixture therein.
The drawback of the tool disclosed in DE 199 62 711 A1 consists in that the combustion process is sensible to the environmental conditions such as, e.g., temperature, scavenging ratio of the combustion chamber, or the environmental pressure. This results from the fact that the turbulence is generated as a result of the combustion process itself, i.e., when the combustion in the forechamber is poor, then the combustion in the main chamber is even worse.
German Publication DE 102 26 878 A1 discloses a combustion-engined setting tool in which, as in the previously described case, the turbulence is generated by a perforated separation plate that remains static before and during the ignition process. After the combustion process ends, the separation plate and the rear wall are displaced in a direction toward the piston guide, so that the combustion chamber completely collapses. After the combustion chamber has collapsed, another, non-perforated plate is displaced as a result of application thereto a spring-biasing force from a location at the rear end of the setting tool remote from the piston guide up to the rear wall in order to scavenge the space before this plate with fresh air.
Here, likewise, the drawback consists in that the combustion process is sensible to the fluctuation of the environmental conditions such as, e.g., temperature, scavenging ratio of the combustion chamber, or the environmental pressure.
The object of the present invention is to provide a setting tool of the type described above and in which the drawbacks of the known tools are eliminated.
Another object of the present invention is to provide a setting tool of the type described above which would have a high energy efficiency.
These and other objects of the present invention, which will become apparent hereinafter, are achieved by providing a setting tool which would include switch means that actuates the ignition unit and that itself is actuated by the turbulence generating means.
Thus, according to the present invention, the ignition unit is directly controlled by the turbulence generating means. When the ignition unit is actuated by the actuation switch means and all of safety switches are closed, then ignition is effected automatically. The ignition takes place during the displacement of the turbulence generating means or as a result of the displacement of the turbulence generating means.
Thereby, ignition of the air-fuel mixture during a turbulent flow regime is insured, which permits to achieve a high energy efficiency of the combustion process. Complex electronics with separate switches for the ignition unit and the turbulence generating means is not any more necessary. Other switches or sensors can be provided, e.g., as safety switches in order to insure, e.g., that the setting tool is indeed pressed against a constructional component.
Advantageously, the turbulence generating means is formed as a member axially displaceable in the combustion chamber and which is actuated by a mechanical device. This measure permits to provide, in a simple way, turbulence in the air-fuel mixture in the combustion chamber, without use of electrical energy from batteries or accumulators, and which is noticeably stronger than the turbulence created, e.g., by flame jets passing through openings formed in a separation plate. In particular, according to the present invention, the turbulence is created in the entire combustion chamber and not only in a sub-chamber, as it takes place when the turbulence is created by flame jets passing through the openings in a separation plate. The mechanical device permits to obtain a pulse acceleration which can provide for displacement of the turbulence generating means in a time period from 1 msec to 200 msec, preferably, from 5 msec to 100 msec. The displacement or operation of the turbulence generating means for such a short time does not require much energy. With a mass of the turbulence generating means from about 1 g to 200, only an energy from about 1 mJ to 1 J is needed. Because of the small energy requirement, it can be obtained, e.g., by pressing the setting tool against the construction component, with the press-on energy being transmitted to the mechanical device, without tiring the user too much.
According to an advantageous embodiment of the present invention, the turbulence generating means is formed as a turbulence generating plate axially displaceable in the combustion chamber and provided, optionally, with openings. The turbulence generating plate can be displaced on a pipe or a rod, which is axially arranged in the combustion chamber, or be only connected with the force storing element, without any guidance. The openings in the turbulence generating plate can be formed as slots or holes. The turbulence generating plate can also be formed as a sieve plate. The turbulence generating plate can also be formed as an arched plate, with the concave side of the turbulence generating plate aligned preferably, in the direction of the pulsed movement. Such a turbulence generating plate has a high aerodynamic drag factor and, therefore, a strong turbulence when moving rapidly. It should be understood that with a collapsed combustion chamber, the displacement of the turbulence generating plate is possible or can take place only in at least partially expanded condition of the combustion chamber.
It is beneficial, when the switch means is provided in the region of a cylindrical wall that radially limits the combustion chamber. With this arrangement, detection of the turbulence generating means passing, in its axial displacement in the combustion chamber, past the switch means is used for actuation of the ignition unit.
Advantageously, the switch means is arranged on a combustion chamber wall that axially limits the combustion chamber. As the switch means, mounting wall, a front, in the setting direction, wall or an opposite rear wall can be used. With this arrangement, detection of engagement of the turbulence generating means with the combustion chamber wall or lifting of the turbulence generating means off the combustion chamber wall is used for the actuation of the ignition unit.
It is beneficial when the switch means is formed as sensor means, which enables a contactless detection of the turbulence generating means or a contactless switching on. Suitable, to this end, sensors are Hall sensors, light-sensitive sensors, or capacitance sensors.
The switch means can also be formed as mechanically actuated switch means, which reduces manufacturing costs of setting tool, without adversely affecting the inventive function. It is advantageous when there is provided time-delay means for delaying the ignition pulse of the switch means. Thereby, by arrangement of the switch means, in particular, in a region that adjoins the piston guide, it can be reliably determined that the turbulence generating means has been displaced by a sufficient amount before the ignition by the ignition unit takes place. As a result, a strong turbulence of the air-fuel mixture in the combustion chamber at the time of ignition prevails.
When set means for adjusting the time delay of the time-delay means is provided, then, in a simple way, the drive-in energy of the inventive setting tool can be adjusted. It has been shown that the produced energy depends on the time the ignition takes-place after actuation of the turbulence generating means. The set means can include, e.g., an adjusting wheel connected with the time-delay means and with which the setting or drive energy can be preset by the user, e.g., there can be provided, on the adjusting wheel, a scale which would indicate the setting energy in absolute (e.g., in J) or relative (e.g., as a %) values.
Instead of an adjusting wheel, the set means can include an adjusting lever or a pressure or sensor switch. Further, the set means can be formed as a sensor system or include such a sensor system. The sensor system can react, e.g., to the type of the constructional component or to the projecting length of a nail obtained from preceding nail settings, and adjust accordingly the setting energy by adjusting the time delay.
The novel features of the present invention, which are considered as characteristic for the invention, are set forth in the appended claims. The invention itself, however, both as to its construction and its mode of operation, together with additional advantages and objects thereof, will be best understood from the following detailed description of preferred embodiments, when read with reference to the accompanying drawings.
The drawing show:
A setting tool 10 according to the present invention, which is shown in
The setting tool 10 has a housing 11 in which there is arranged a setting mechanism with which a fastening element such as a nail, a bolt or the like can be driven in a constructional component U (
The setting mechanism includes, among others, a combustion chamber casing 12 in which a combustion chamber 13 is expandable, a piston guide 17 in which a setting piston 16 is displaceably arranged, and a bolt guide 18 in which a fastening element can be displaced by setting direction end of the forward movable setting piston 16 and, thereby, be driven in a constructional component. The fastening element can, e.g., be stored in magazine 27 on the setting tool 10.
The combustion chamber 12 is displaceably arranged with respect to the piston guide 17 and is elastically biased by a spring, not shown in the drawings, in a direction toward the bolt guide 18 or in a direction of a collapsed position of the combustion chamber 13 shown in
An electrical conductor 45 connects the ignition element 23 with switch means 22, which is formed as sensor switch means and with which an ignition process is actuated as it would be described more precisely below.
The switch means 22 is formed, in the embodiment shown in the drawings, as a Hall sensor arranged on a cylindrical wall 54 of the combustion chamber casing 12. Alternatively, the switch means 22 can also be formed, e.g., as an optical or capacitance switch. The switch means 22 can also be formed as a mechanical or electronic switch.
Through an air inlet 51 in the housing 11 and an inlet opening 15 in the rear wall 14 of the combustion chamber 13, air can be brought into the combustion chamber 13 (as shown with arrow 41) when the combustion chamber expands as a result of displacement of the combustion chamber casing 12 in the direction of arrow 40 (please see
In the expanded condition of the combustion chamber casing 12 or the combustion chamber 13, a mechanical device, which is generally designated with a reference numeral 30, for a pulsed acceleration of turbulence generating means 32 is activated. The turbulence generating means 32 is formed as a turbulence generating plate 33 provided with openings 38. The mechanical device 30 includes a force storing element 31 which is formed as a spring engaging, with one of its end, the turbulence generating plate 33 and with its other end, the rear wall 14 of the combustion chamber 13. The turbulence generating means 32 or the turbulence generating plate 33 is displaced substantially friction-free along the tubular element 20 and is sufficiently spaced from the cylindrical wall 54 of the combustion chamber casing 12, so that no friction losses occur during displacement of the turbulence generating plate 33 in an axial direction in the combustion chamber 13.
In the initial or inoperative position of the setting tool 10 shown in
When the setting tool 10, as shown in
During the expansion process of the combustion chamber 13, on one hand, air flows into the combustion chamber 13 through the air inlet 51 and the inlet opening 15 in the direction of arrow 41 and, on the other hand, fuel 50 is fed into the combustion chamber 13 through the fuel conduit 21. The fuel conduit 21, only a section of which is shown in
When the setting tool 10, as shown in
In the position of the setting tool 10 shown in
When the turbulence generating plate 33 reaches the switch means 22 or the Hall sensor, the later is actuated and communicates an ignition pulse to the ignition unit 23 through the conduit 45. The ignition unit 23 ignites the air-fuel mixture, as shown with reference numeral 24. If the switch means 22 is formed as a mechanical or electronic switch, it can likewise be actuated by the displaceable turbulence generating plate 33, closing the ignition circuit. In every case, the ignition takes place automatically and is actuated by the turbulence generating means 32 or the turbulence generating plate 33. Thereby, the ignition 24 always takes place during the displacement of the turbulence generating means 32 at a time when the air-fuel mixture in the combustion chamber 13 is subjected to a strong turbulence. Thereby, a very high energy yield during the combustion process is achieved.
The setting piston 16 is displaced by the expandable gases in the direction of arrow 43 toward the bolt guide 18, driving a fastening element in the constructional component U. At the end of the piston guide 17 adjacent to the bolt guide 18, there is provided an annular damping element 26 that damps or prevents overrun of the setting piston 16 at this end of the piston guide 17.
In the wall of the piston guide 17, there is provided an outlet opening 19 through which a major portion of the combustion gases can reach the exhaust opening 52 in the housing 11 and therethrough be released into environment when the piston plate 56 of the setting piston 16 is located between the outlet opening 19 and the damping element 26.
In
The setting tool 10, which is shown in
In the setting tool 10 shown in
Though the present invention was shown and described with references to the preferred embodiments, such are merely illustrative of the present invention and are not to be construed as a limitation thereof, and various modifications of the present invention will be apparent to those skilled in the art. It is, therefore, not intended that the present invention be limited to the disclosed embodiments or details thereof, and the present invention includes all variations and/or alternative embodiments within the spirit and scope of the present invention as defined by the appended claims.
Number | Date | Country | Kind |
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10 2004 043 950 | Sep 2004 | DE | national |
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Number | Date | Country | |
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20060054115 A1 | Mar 2006 | US |