EP0621110A1 - Powder-actuated driving tool - Google Patents

Abstract

The powder-actuated driving tool has a piston return mechanism operating through the use of compressed propellant gases. For this purpose, propellant gases pass from an opening (6) via a passage (5) through an opening (7) into the guide bore (2a) of a piston guide (2). The piston (1) is driven by the compressed propellant gases from its front end position into its rear initial position until it comes to bear on the base (4c) of a cartridge carrier (4). While the piston (1) comes to a stop, the cartridge carrier (4) is displaced to a limited extent against the driving direction. For this purpose, the cartridge carrier (4) is connected to a housing part (3) via a buttress thread (3a, 4a) exhibiting backlash. <IMAGE>

Description

The invention relates to a powder-powered setting tool with a piston guide, within the guide bore of which propellant gases are used to propel a piston from a rear starting position from a cartridge holder forming the rear stop for the piston into a front end position, with the piston guide and a housing part surrounding it a channel is provided which is connected to the guide bore of the piston guide via openings in the initial position area and in the end position area of the piston.

In the case of powder-operated setting tools of the type in question, a piston is driven by the propellant gases of a propellant charge that comes to ignition from a rear starting position into a front end position. The piston acts on bolts, nails and the like fasteners which are driven directly into hard receiving materials such as concrete, metal and the like.

In order to bring the piston into the ready position for the next driving-in process after a completed driving-in process, it is necessary to move the piston from its front end position to its rear starting position. This process can be carried out in various ways in known devices.

It is known, for example, to return the piston to its rear starting position by means of a separate tappet. This process has the disadvantage that on the one hand it is quite time-consuming and on the other hand it requires a separate plunger, which can easily be lost.

Furthermore, a mechanical, device-side feedback device has become very popular, which consists in pulling the piston guide forward over the piston in the front end position and then pushing the piston guide and the piston arranged therein back, so that the piston ultimately comes to lie in its rear starting position.

This type of piston return is also relatively time-consuming due to its separate manipulation effort, which has a disadvantageous effect in particular in the case of series fastenings, such as are carried out with the devices in question.

In order to counter the above-mentioned, special manipulation effort, a piston return using the propellant gases has become known, for example, from EP 0 223 740. With this type of piston return, an opening in the initial position area of the piston is released after the ignition of the piston which is set in motion, so that through this opening residual propellant gases pass through an opening in the end position area of the piston into the guide bore of the piston guide. These propellant gases, which have entered the guide bore of the piston guide, are compressed by the piston and serve, under their relaxation, to drive the piston back from its front end position into its rear starting position after the driving-in process has been completed.

This type of piston return, which is still known, therefore has the advantage that it takes place completely automatically, without any further manipulation effort. The omission of all mechanical measures leads to the problem that, depending on the degree and the amount of compressed propellant gases, the piston is driven more or less strongly against the rear stop formed by the cartridge carrier. With a high degree and a large proportion of compressed propellant gases, the disadvantage can arise that when the piston strikes the cartridge carrier, a rebound effect arises, which has the consequence that the piston is driven in a certain way in the driving direction again due to this rebound effect and thus does not assume its rear starting position. This can have the consequence that there is so much dead space available during the subsequent driving-in process that the desired performance of the setting tool is not achieved or that even the opening arranged in the starting position area remains open and a large part of the propellant gases are not available for operating the piston.

The invention has for its object to provide a powder-powered setting tool which has a piston return acting by using the propellant gases, in which a retention of the piston in its rear starting position is ensured in the cartridge carrier forming the rear stop for the piston.

According to the invention, the object is achieved in that the cartridge carrier of the setting tool can be displaced to a limited extent along the axis of the piston relative to the other device parts.

The limited displaceability of the cartridge carrier relative to the other parts of the device means that a rebound effect is avoided when the piston is driven from its front end position against its rear starting position due to the action of the compressed propellant gases. As soon as the piston hits the rear stop formed by the cartridge carrier, the energy of the piston is transferred to the cartridge carrier in accordance with the laws of the pulse set, so that the piston stands still and instead of the piston the cartridge carrier is driven against the setting direction. Due to the limited displaceability, this movement takes place in an extremely limited frame that does not lead to a harmful dead space.

A simple design of a setting tool according to the invention is expedient if the cartridge carrier can be displaced to a limited extent along the axis of the piston relative to the housing part surrounding the piston guide. The limited displaceability between the cartridge carrier and the housing part is preferably accomplished by a connection which allows the limited displaceability. Such a connection expediently has stops on one part and counter-stops on the other part.

In a preferred manner, a threaded connection is provided as a connection between the cartridge carrier and the housing part. Such a threaded connection enables simple assembly and disassembly of the setting tool, for example in the event of any necessary replacement of device parts or in the event of disassembly for the purpose of cleaning the setting tool.

Among the large number of possible threaded connections, a sawtooth thread is suitable, for example, which is expediently designed such that its flatter flanks run counter to the setting direction toward the axis of the piston. A sawtooth thread designed in this way creates a type of conical surfaces and counter-conical surfaces which run against one another when the impact occurs. This makes it possible for a large part of the energy to be converted into friction and heat in the area of these cone surfaces and counter-cone surfaces.

The aforementioned conversion of the energy introduced into the cartridge carrier can be further supported, for example into elastic deformation, expediently in such a way that the cartridge carrier has open slots in the area of the threaded connection towards its free end. As a result, the cartridge carrier is additionally elastic in the area of the threaded connection through shaping, that is to say in addition to its elasticity which may already be present due to the choice of material.

It has been shown that the rebound effect can be prevented with a very limited displacement. Even small distances are sufficient in terms of displaceability, which are expediently in the range from 0.1 to 0.3 mm. These small distances create a movability of the cartridge carrier, which does not yet lead to a harmful dead space.

With regard to the avoidance of a potentially harmful dead space, not only the small distances are crucial, but also the behavior of the cartridge holder after impact. For example, in the case of a proposed threaded connection, the thread flanks of the cartridge carrier run up on the counter flanks of the housing part after the limited displacement has been used up, which in turn leads to a - however reduced - rebound effect and drives the cartridge carrier back into its original position in the setting direction. This effect is also supported by the elasticity of the cartridge carrier - be it due to the choice of material or the shape.

Based on the impulse set, the mass ratios also play a role in connection with the avoidance of the rebound effect. It is advantageous if the mass of the cartridge carrier corresponds at least to the mass of the piston. However, the mass ratios are preferably designed in such a way that the mass of the cartridge carrier corresponds approximately to 1 to 3 times the mass of the piston. The influencing factors that lead to such a mass selection are formed in particular by the friction conditions and the material properties of the parts concerned.

Fig. 1

die im Zusammenhang mit der Erfindung massgebenden Geräteteile eines pulverkraftbetriebenen Setzgerätes im Schnitt;

Fig 2

der im Zusammenhang mit der Erfindung massgebende Verbindungsbereich in vergrösserter, geschnittener Darstellung.

The invention is explained in more detail below with reference to drawings which show an exemplary embodiment. Show it:

Fig. 1

the relevant in connection with the invention device parts of a powder-operated setting tool in section;

Fig. 2

the decisive connection area in connection with the invention in an enlarged, sectional view.

In view of the fact that powder-operated setting tools are known and device parts such as bolt guide, ignition mechanism, trigger mechanism and the like have no influence on the present invention, FIG. 1 is limited to the device parts which are decisive in connection with the present invention.

1 shows a piston 1 which is guided in a piston guide 2. For this purpose, the piston guide 2 has a guide bore 2a. The piston guide 2 is surrounded by a housing part 3 which is connected to a cartridge carrier 4. A sawtooth thread 3a, 4a serves to connect the housing part 3 and the cartridge carrier 4.

1 also shows, the cartridge carrier 4 has a receiving bore 4b for the rear region 1a of the piston 1. The bottom 4c of the receiving bore 4b forms on the cartridge carrier 4 the rear stop for the piston 1 in its rear starting position. The cartridge carrier 4 is also provided with a cartridge receptacle 4d, which is connected to the receiving bore 4b via a through hole 4e.

Between the housing part 3 and the piston guide 2, a channel 5 is provided, which continues in the area of the cartridge carrier 4 against the setting direction. The channel 5 is connected to the guide bore 2a of the piston guide 2 via an opening 6 in the initial position area and an opening 7 in the end position area. The opening 7 in the end position region opens into the guide bore 2a in front of a pin guide 8 which serves to guide the piston shaft 1b.

As shown in FIG. 2 in particular, there is play between the individual flanks of the sawtooth thread 3a, 4a. This play enables a limited axial displaceability of the cartridge carrier 4 relative to the housing part 3. The play between the flanks of the sawtooth thread 3a, 4a is designed such that the extent of the limited axial displaceability between the cartridge carrier 4 and the housing part 3 along the axis of the piston 1 is approximately 0 , 1 mm to 0.3 mm.

The effect of the piston return according to the invention is such that after a propellant charge is ignited within the cartridge receptacle 4d, the propellant gases pass through the through hole 4e and act on the piston 1 such that it is driven from its rear starting position to its front end position. The rear region 1a of the piston 1 leaves the receiving bore 4b, so that a remaining portion of the propellant gases reaches the channel 5 via the opening 6. These propellant gases pass through the opening 7 from the channel 5 into the guide bore 2a, where they are compressed by the piston 1. Because of these compressed propellant gases, the piston 1 is driven from its front end position back to its rear starting position after the driving-in process has been completed. The rear region 1a of the piston 1 hits the bottom 4c of the cartridge carrier 4, which has the consequence that the piston 1 stops due to the shock transmission and the cartridge carrier 4 is driven counter to the setting direction until the limited axial displaceability is used up is. In the present example, this limited axial displaceability is determined by the play between the flanks of the sawtooth thread 3a, 4a. The effect can be supported by material-related or shape-related elasticity of the cartridge carrier 4, the shape-related, for example by a slot 4f in the area of the sawtooth thread 3a, 4a. Due to the elastic effect and due to the rebound effect between the tooth flanks after the game has been used up, the cartridge carrier 4 is again driven in the setting direction, so that it assumes its original position shown in FIG. 1, in which there is no dead space between the rear region 1 a of the piston 1 and Bottom 4c of the receiving bore 4b is present.

Claims (8)

1. powder-operated setting tool with a piston guide (2), within the guide bore (2a) of a propellant charge, a piston (1) from a rear starting position from a cartridge holder (4) forming the rear stop for the piston (1) into a cartridge holder Front end position can be driven, a channel (5) being provided between the piston guide (2) and a housing part (3) surrounding it, which channel has openings (6, 7) in the initial position area and in the end position area of the piston (1) with the guide bore (2a ) is connected, characterized in that the cartridge carrier (4) can be displaced along the axis of the piston (1) to a limited extent with respect to the other device parts. 2. Powder-powered setting tool according to claim 1, characterized in that the cartridge carrier (4) along the axis of the piston (1) relative to the piston part (2) surrounding the housing part (3) is displaceable to a limited extent. 3. Powder-powered setting tool according to claim 2, characterized in that between the cartridge carrier (4) and housing part (3) is provided a connection allowing limited displacement. 4. Powder-powered setting tool according to claim 3, characterized in that a threaded connection is provided as a connection between the cartridge carrier (4) and the housing part (3). 5 powder-powered setting tool according to claim 4, characterized in that the threaded connection is formed by a sawtooth thread (3a, 4a), the flatter flanks of which run counter to the setting direction towards the axis of the piston (1). 6. Setting tool according to claim 4 or 5, characterized in that the cartridge carrier (4) has open slots (4f) in the area of the threaded connection towards the free end. 7. Setting tool according to one of claims 1 to 6, characterized in that the measure of the limited displaceability measured along the axis of the piston is 0.1 mm to 0.3 mm. 8. Setting tool according to one of claims 1 to 7, characterized in that the mass of the cartridge carrier (4) corresponds approximately to 1 to 3 times the mass of the piston (1).

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