Patent Grant
11204046
This patent application is the U.S. National Stage of International Patent Application No. PCT/EP2016/081897, filed Dec. 20, 2016, which claims the benefit of European Patent Application No. 15201895.8, filed Dec. 22, 2015, which are each incorporated by reference.
The invention relates to a fuel-operated firing device for driving securing elements into a substrate, comprising at least one main combustion chamber for a fuel, a driving piston which can be driven out of the main combustion chamber in a firing direction by means of expandable gases, and a pre-chamber with which an ignition device is associated and in which a pressure acting on the main combustion chamber can build up prior to a fuel/air mixture being ignited in said main combustion chamber. Furthermore, the invention relates to a method for operating such a firing device.
German unexamined patent application DE 10 32 035 A1 discloses a fuel-operated firing device for driving securing elements into a substrate, comprising at least one main combustion chamber for a fuel, a driving piston which is mounted in a piston guide and can be driven out of the main combustion chamber in the firing direction by means of expanding gases, and a pre-chamber with which an ignition device is associated and in which a pressure acting on the main combustion chamber can build up prior to a fuel/air mixture being ignited in said main combustion chamber, wherein the pre-chamber is formed by a space inside the piston guide which adjoins the underside, remote from the main combustion chamber, of the driving piston located in its starting position, and wherein the pre-chamber is connected to the main combustion chamber at least intermittently via a passage, wherein in the main combustion chamber a means for detection of the pressure is provided, which interacts with the ignition device for the main combustion chamber. German unexamined patent application DE 42 43 36 17 A1 discloses a handheld, fuel-operated working device, in particular a firing device for securing elements, having a cylindrical combustion chamber for combustion of an air/fuel mixture, so that a ram can be driven by means of a piston guided through the combustion chamber, wherein a pre-chamber is provided which communicates with an underneath surface of the piston facing away from the combustion chamber and in which an ignition-induced combustion process of an air/fuel mixture can be initiated for the substantially isentropic compression of the air/fuel mixture in the combustion chamber.
The object of the invention is to improve the effectiveness and/or functionality during the driving in of securing elements using a fuel-operated firing device, at least one main combustion chamber for a fuel, a driving piston which can be driven out of the main combustion chamber in a firing direction by means of expandable gases, and a pre-chamber with which an ignition device is associated and in which a pressure acting on the main combustion chamber can build up prior to a fuel-air mixture being ignited in said main combustion chamber.
In a fuel-operated firing device for driving securing elements into a substrate, comprising at least one main combustion chamber for a fuel, a driving piston which can be driven out of the main combustion chamber in a firing direction by means of expandable gases, and a pre-chamber with which an ignition device is associated and in which a pressure acting on the main combustion chamber can build up prior to a fuel-air mixture being ignited in said main combustion chamber, this object is achieved in that the pre-chamber has at least two venting connections spaced apart from one another in an axial direction and having through openings which can in particular be closed and exposed in order to enable rapid venting of the pre-chamber. The term “axial” relates to a longitudinal axis or movement axis of the driving piston. The driving piston is preferably substantially rotationally symmetrical. In operation of the fuel-operated firing device the driving piston is guided movably back and forth in the direction of its longitudinal axis. “Axial” means in the direction of or parallel to the movement axis of the driving piston. The through openings of the venting connections preferably extend in radial directions, that is to say transversely with respect to the longitudinal axis of the driving piston.
A preferred exemplary embodiment of the fuel-operated firing device is characterized in that a first venting connection in the axial direction is spaced further apart from the main combustion chamber than a second venting connection. The main combustion chamber is preferably arranged coaxially with respect to the pre-chamber. An end of the pre-chamber remote from the main combustion chamber is also designated as a firing end. An extremely rapid movement of the driving piston in operation of the firing device is also designated as a piston flight. The first venting connection advantageously serves to provide a large venting cross section if the pre-chamber is to be scavenged by a piston flight. During operation of the firing device, by means of both venting connections the old gas can be displaced over the piston flight path. The second venting connection advantageously serves during a first piston flight phase to discharge the residual gases located in the pre-chamber. The effective cross section for the ventilation of the pre-chamber can be significantly increased by the two venting connections. In a second piston flight phase, if a piston head or piston plate has travelled over the second venting connection, the combustion gases from the main combustion chamber can be discharged over the venting cross section of the second venting connection. As a result, a thermal piston return is enabled in a simple manner by formation of negative pressure in the main combustion chamber.
A further preferred exemplary embodiment of the fuel-operated firing device is characterized in that the first venting connection is arranged in the vicinity of a stop and/or damping element for the driving piston. The stop and/or damping element or a plurality of stop and/or damping elements constitute a buffer device for the driving piston. The buffer device is advantageously arranged on an end of the pre-chamber, which end faces away from the main combustion chamber and corresponds to the firing end.
A further preferred exemplary embodiment of the fuel-operated firing device is characterized in that the venting connections in each case comprise a series of through openings in a pre-chamber cylinder. The through openings are spaced uniformly apart from one another in the pre-chamber cylinder, preferably in a circumferential direction. A large effective venting cross section can be provided in a simple manner by a corresponding number and size of the passage openings in the pre-chamber cylinder.
A further preferred exemplary embodiment of the fuel-operated firing device is characterized in that the venting connections comprise through openings in a control sleeve which, in an open position of the control sleeve, are made to overlap the through openings of the pre-chamber cylinder in order to expose the venting connections, in particular jointly. The control sleeve is preferably configured and movable relative to the through openings of the pre-chamber so that the through openings of the pre-chamber are exposed or closed by the control sleeve depending upon a main combustion chamber pressure. The control sleeve has, for example, substantially the configuration of a straight circular cylindrical shell, which is movable relative to the pre-chamber cylinder, which delimits the pre-chamber, between the open position, in which the through openings of the pre-chamber are exposed or opened, and a closed position, in which the through openings the pre-chamber are closed.
A further preferred exemplary embodiment of the fuel-operated firing device is characterized in that the control sleeve is combined with a non-return valve device for the venting connections which opens in the event of a positive pressure in the pre-chamber if the control sleeve is in the open position. In the event of a positive pressure in the pre-chamber, the non-return valve device enables the venting connections to be opened towards the surroundings. As a result the positive pressure in the pre-chamber can be reduced in a simple manner if the control sleeve is in its open position. The non-return valve device comprises, for example, closure elements which are designed as non-return lamellas. The non-return lamellas expose the venting connections only above a certain positive pressure in the pre-chamber and close the venting connections again as soon as the positive pressure in the pre-chamber is reduced. As a result an undesirable flowing back of exhaust gases from an exhaust gas system into the pre-chamber of the bolt firing device is prevented. According to a further aspect of the invention the non-return valve device, in particular the non-return lamellas, can also be installed independently of the control sleeve in a further configuration of the exhaust gas system. As a result it is possible to reduce undesirable dynamic influences arising out of movements of the control sleeve due to the firing process.
A further preferred exemplary embodiment of the fuel-operated firing device is characterized in that the non-return valve device comprises closing elements made of a spring steel material. The closing elements made of the spring steel material comprise, for example, valve elements which are in each case associated with two through openings of different venting connections. The valve elements are connected to one another, for example, by a connecting ring member. The connecting ring member can likewise be formed of spring steel material.
A further preferred exemplary embodiment of the fuel-operated firing device is characterized in that a pre-chamber inlet is provided at an end of the pre-chamber cylinder remote from the main combustion chamber. The two venting connections are closed by the control sleeve during pre-combustion. During a main combustion the two venting connections are exposed by the control sleeve, that is to say for the discharge of exhaust gases in front of the piston in the pre-chamber. In order that the exhaust gases just discharged are not drawn in again, the control sleeve is combined with the previously described non-return valve device. Fresh air is then drawn in as required through the additional pre-chamber cylinder inlet on the end of the pre-combustion chamber remote from the main combustion chamber. The fresh air is then advantageously drawn in through the pre-chamber inlet into the pre-chamber if a negative pressure in the cooling main combustion chamber retracts the driving piston.
Furthermore, the invention relates to a method for operating a previously described fuel-operated firing device. The pre-chamber can advantageously be opened by means of the two venting connections quickly enough so that the driving piston does not run in an undesirable manner onto an exhaust gas cushion runs and thus lose power. In a firing operation all of the pre-chamber exhaust gases can be discharged rapidly and effectively into the environment by means of the two venting connections. The venting by means of the two venting connections is also designated as double pre-chamber venting. The double pre-chamber venting enables a very rapid counter-pressure reduction in the pre-chamber and ultimately leads to a higher device energy, since the driving piston does not run onto an exhaust gas cushion or into an exhaust gas cushion. The non-return valve device, which is combined with the control sleeve and can also be arranged in the further course of the exhaust gas system, prevents an undesirable intake of old gas in a simple manner during the thermal return of the driving piston. The non-return valve device ensures in a simple manner that only fresh air is drawn in via the pre-chamber intake, which can also be designated as a pre-chamber inlet. Furthermore, the non-return valve device advantageously prevents dirt from collecting in the region of the venting connections and prevents damage to any seals which may be provided in the region of the venting connection.
Furthermore, the invention relates to a control device, a control sleeve, a pre-chamber cylinder and/or a non-return valve device for a previously described firing device. Said parts can be handled separately.
Further advantages, features and details of the invention are apparent from the following description in which various embodiments of the invention are described in detail with reference to the drawings. In the drawings:
In
The bolt guide with the piston rod 11 of the driving piston 10 arranged therein is also designated as a firing unit. By means of the firing unit a securing element, such as a nail, bolt or the like, can be driven into a substrate (not shown). Before the firing of a securing element, the firing device 1 with its bolt guide is pressed onto the substrate and triggered. A switch (not shown) which is also designated as a trigger switch serves, for example, for triggering a firing operation. The switch is provided, for example, on a handle (likewise not shown) of the firing device 1.
A firing device is indicated by an arrow 15 in
A movement of the driving piston 10 towards the right in
A movement of the driving piston 10 towards the left is delimited by stop and/or damping elements 28, 29. The stop and/or damping elements 28 constitute a buffer 110. The piston head 12 comprises a first piston surface 21 which faces the main combustion chamber 6. A second piston surface 22, which faces away from the main combustion chamber 6, delimits a pre-chamber 25 in a pre-chamber cylinder 24.
The pre-chamber 25 constitutes a pre-combustion chamber with which an ignition device 26 and an inlet device 27 are associated. Furthermore, the stop and/or damping elements 28, 29 are arranged in the pre-chamber 25. A gas/air fuel mixture, which is ignited with the aid of the ignition device 26 in the pre-chamber 25, is supplied to the pre-chamber or pre-combustion chamber 25 by means of the inlet device 27.
The pre-chamber cylinder 24 comprises through openings 31, 32 which, for example, enable the exhaust gases to exit the pre-chamber 25. The through openings 31, 32 can be closed as required by a control device 30. The control device 30 comprises a control sleeve 34 which has through openings 37, 38.
If the through openings 37, 38 of the control sleeve 34 are made to overlap the through opening 31, 32, then the through openings 31, 32 are opened, as can be seen in
Overflow openings 41, 42 are provided between the pre-chamber 25 and the main combustion chamber 6. A valve device 43, 44 is associated with each of the overflow openings 41, 42. The valve devices 43, 44 are, for example, valve flaps which enable a passage of an ignited air/fuel mixture from the pre-chamber 25 into the main combustion chamber 6.
The control device 30 comprises a control pressure surface 45, which is connected to the main combustion chamber 6 for control pressure purposes. The control pressure surface 45 is designed as an annular surface 46 which faces the main combustion chamber 6 radially outside the pre-chamber cylinder 24. The control pressure surface 45 is coupled mechanically to the control sleeve 34 by means of a coupling element 48.
The coupling element 48 is designed as a slider 50 which, in
Furthermore, the control device 30 comprises spring devices 54, 55 which are designed, for example, as helical compression springs. Housing-mounted stops 56, 57 are in each case associated with the left-hand ends of the spring devices 54, 55 in
The spring devices 54, 55 are clamped between the housing-mounted stops 56, 57 and the right-hand end 51 of the slider 50 having the control pressure surface 45. Thus, the slider 50 is supported on the housing-mounted stops 56, 57 by means of the spring devices 54, 55.
In
The main combustion chamber 6 is delimited by a combustion chamber sleeve 84 which can be moved to a limited extent in the axial direction in order to enable scavenging of the main combustion chamber 6. A fan 80 is arranged in the main combustion chamber 6.
In
In
As described below, fuel gas is injected into the pre-chamber 25 by means of the inlet device 27 and into the main combustion chamber 6 by means of the inlet device 8. During injection of the fuel gas into the pre-chamber 25 and into the main combustion chamber 6 the fan 80 rotates in the main combustion chamber 6.
The ignition of the gas mixture is initiated by the ignition device 26 which is associated with the pre-chamber 25 and located in the vicinity of the buffer 110. After the ignition of the gas mixture in the pre-chamber 25, a flame front propagates, travelling from the side of the buffer 110 in the direction of the main combustion chamber 6, that is to say towards the right in
The overflow from the pre-chamber 25 into the main combustion chamber 6 takes place by means of the overflow openings 41, 42 with the valve devices 43, 44 open. The valve devices 43, 44 are, for example, designed as non-return valves which expose the overflow openings 41, 42, which are also designated as ignition openings, during propagation of the laminar flame front.
When the flame front has reached the non-return valves of the valve devices 43, 44, the flame can pass via the non-return valves into the main combustion chamber 6 for ignition, so that the main chamber combustion is initiated in the main combustion chamber 6. In
During the main chamber ignition 86 the pressure in the main combustion chamber 6 rises and the control sleeve 34 is pushed forwards, that is to say towards the left in
The pre-chamber pressure escaping from the pre-chamber 25 by means of the opened venting connections 108, 109 is indicated by arrows 91 to 94 in
In
After the firing a negative pressure is produced in the main combustion chamber 6 by cooling of the bolt firing device 1. This negative pressure in the main combustion chamber 6 leads to the driving piston 10 being retracted or drawn back into its starting position. In this case fresh air is sucked or drawn into the pre-chamber 25 of the bolt firing device 1 through a pre-chamber inlet 140 on the left-hand end of the pre-chamber cylinder 24 in
A non-return valve on one side is advantageously associated with the pre-chamber inlet 140. The non-return valve comprises, for example, a relatively large spring lamella, which enables fresh air to be drawn into the pre-chamber 25, but in the reverse direction it prevents unwanted outflow of pressurized fuel/air mixture out of the pre-chamber 25 into the environment.
When the bolt firing device 1 with the firing end 14, which is shown truncated in
The control device 30 is illustrated alone in different views in
The coupling 100 is fixedly connected to a connecting flange 105 by means of slider rods 101, 102, 103 which partially constitute the slider 50. The connecting flange 105 connects the control sleeve 34 to the slider rods 101 to 103. On the other hand, the slider rods 101 to 103 are connected by means of a connecting flange 98 to the coupling sleeve 100. A spring device 54, 55 designed as a compression spring is associated with each slider rod 101 to 103. In the installed state of the control device 30 the spring devices 54, 55 are clamped between the connecting flange 98 and the housing-mounted stops 56, 57 on the pre-chamber cylinder 24.
The control sleeve 34 serves to expose the through openings 31, 32; 117, 118 in the pre-chamber cylinder 24 as required, as indicated in
In
| Number | Date | Country | Kind |
|---|---|---|---|
| 15201895 | Dec 2015 | EP | regional |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/EP2016/081897 | 12/20/2016 | WO | 00 |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2017/108772 | 6/29/2017 | WO | A |
| Number | Name | Date | Kind |
|---|---|---|---|
| 4483473 | Wagdy | Nov 1984 | A |
| 4913331 | Utsumi | Apr 1990 | A |
| 5000128 | Veldman | Mar 1991 | A |
| 5497929 | Armstrong | Mar 1996 | A |
| 5909836 | Shkolnikov et al. | Jun 1999 | A |
| 6755159 | Adams et al. | Jun 2004 | B1 |
| 7427007 | Shima et al. | Sep 2008 | B2 |
| 7703648 | Tamura | Apr 2010 | B2 |
| 20040079302 | Wolf et al. | Apr 2004 | A1 |
| 20040144357 | Adams | Jul 2004 | A1 |
| 20050001000 | Favre-Bulle et al. | Jan 2005 | A1 |
| 20050173486 | Moeller et al. | Aug 2005 | A1 |
| 20090250499 | Hahn et al. | Oct 2009 | A1 |
| 20100065602 | Zhao et al. | Mar 2010 | A1 |
| 20150343625 | Ricordi | Dec 2015 | A1 |
| 20160144497 | Boehm et al. | May 2016 | A1 |
| Number | Date | Country |
|---|---|---|
| 1042217 | May 1990 | CN |
| 1134681 | Oct 1996 | CN |
| 1217967 | Jun 1999 | CN |
| 1494989 | May 2004 | CN |
| 40 10 517 | Oct 1991 | DE |
| 42 43 617 | Jun 1994 | DE |
| 102 32 035 | Jan 2004 | DE |
| 103 27 191 | Dec 2004 | DE |
| 2 106 883 | Oct 2009 | EP |
| 2 826 601 | Jan 2015 | EP |
| 2007-521974 | Aug 2007 | JP |
| WO 2017108782 | Jun 2017 | WO |
| WO 2017108787 | Jun 2017 | WO |
| Entry |
|---|
| International Bureau, International Search Report in International Application No. PCT/EP2016/081897, dated Apr. 13, 2017. |
| Number | Date | Country | |
|---|---|---|---|
| 20200271141 A1 | Aug 2020 | US |
