SE463249B - POWDER-DRIVEN TOOL FOR RECOVERY OF FAESTORGAN - Google Patents

Description

,65 10 15 20 25 30 35 249 2 simply "No. 5" cartridge) with a light fastener (for example, a nail with a length of 12 mm and still consider the tool to be operating at "low speed". In this regard, it should be noted that a "low speed" tool is one that has a maximum velocity of 91.4 m/s measured 1.8 m from the nozzle. Another problem with many powder-actuated fastener driving tools is that they have a design that does not allow easy disassembly in the field for ease of inspection. Another common limitation of the designs to date is that they cannot be easily adapted to drive fasteners of different types and dimensions. Existing powder-actuated fastener driving tools typically cannot be adapted for mounting on a rod assembly or otherwise the rod assemblies available for such tools are unsuitable for use or allow for unintentional firing. ing.

In addition to the above-mentioned problems, which are common to many existing tools, at least one tool of this type uses a triggering assembly which is relatively complicated, which increases the above-mentioned problems of expensive manufacture, difficult assembly and tendency to mechanical failure. In addition, at least one known powder-actuated fastener driving tool uses a cam arrangement in its cartridge displacement mechanism, which has a tendency to wear excessively, requiring increased supervision if binding is to be avoided.

A main object of the invention is to provide a powder-powered tool for driving fasteners, which is specially adapted to eliminate the above-mentioned problems which occur with known tools of the type in question.

A more specific object of the invention is to provide a powder-powered tool for driving magazine-type fasteners which is relatively inexpensive to manufacture, relatively easy to assemble, reliable in operation and substantially jam-free. 10 15 20 25 30 35 461% 249 3 The objects of the invention are achieved in that the trigger device consists of a trigger lever, a first pin which rotatably supports the trigger lever for movement towards and away from the firing mechanism, a torsion spring which is connected to the trigger lever and a second pin to thus resiliently bias the trigger lever away from the firing mechanism, a trigger and a trigger push rod which connects the trigger to the trigger lever to thus cause the trigger to press the trigger lever in the direction for operating the locking member when the trigger is actuated, whereby the firing actuator is caused to drive the firing pin forward for firing a cartridge located in line with the cylinder member.

The invention will be described in more detail below with reference to the accompanying drawings, which show exemplary embodiments and in which the same reference numerals refer to the same parts. Fig. 1 shows in longitudinal section with certain portions illustrated from the side and certain portions broken away a powder-powered tool for driving fasteners, which is a preferred embodiment of the invention. Fig. 2 shows in perspective and section with slightly separated parts portions of the tool housing assembly and a cartridge displacement mechanism. Fig. 2A shows a section along the line 2A-2A in Fig. 2 with certain portions broken away. Fig. 2B shows a section along the line 2B-2B in Fig. 2. Fig. 3 shows the tool barrel in perspective.

Fig. 4 shows the cylinder member of the tool in perspective. Fig. 4A shows the cylinder member in longitudinal section. Fig. 5 shows in perspective the same cylinder member seen from a different angle.

Fig. 6 shows the hand guard of the tool in perspective with some parts broken away. Fig. 7 shows the firing pin assembly of the tool in perspective. Fig. 8 shows the tool cylinder stop assembly in perspective with some parts broken away. Fig. 9 shows the tool ejector block assembly in perspective with some parts broken away. Fig. 10 shows the tool firing mechanism in perspective with some parts broken away.

Fig. 11 is a front view of a cartridge carrier strip used with the tool. Fig. 12 is a side view of a plurality of cartridges arranged in the same strip. Fig. 13 is a cross-sectional view taken along line 13-13 of Fig. 1 of portions of the tool housing assembly, ejector block assembly, cartridge advancing mechanism, and trigger assembly. Fig. 14 is a perspective view, with parts slightly separated, of a fastener assembly used with the tool. Figs. 15A and 15B are longitudinal sectional views, with some parts in side elevation and some parts broken away, of a rod assembly suitable for use with the tool. Fig. 16 is a top view of the trigger actuating portion of the rod assembly, and Fig. 17 is a handle and cam portions of the rod assembly, with parts slightly separated.

A powder-actuated fastener driving tool is shown in Figure 1, which is a preferred embodiment of the invention. The tool consists essentially of a housing assembly, which in part consists of a housing 100 and a rear cover 141, a barrel and cylinder assembly 200, a firing pin assembly 300, a cylinder stop assembly 400, an ejector block assembly 500, a firing mechanism 600, a trigger assembly 700 and a cartridge displacement mechanism 800.

Referring to FIGS. 1, 2, 2A and 2B, the housing 100 has a front bore 104, a front counterbore 106 communicating with the front bore 104 and forming a shoulder 108 at the junction therebetween, a rear bore 110, a rear counterbore 112 communicating with the rear bore 110, a hollow handle section 113 and an irregular, transversely extending chamber 116 extending from the top of the tool to the lower end of the handle section 113 and intersecting and communicating with the front bore 104.

The handle section 113 has an elongated opening 111 at its rear side, which communicates with the chamber 116, and the housing 100 has a recessed opening 10 15 20 25 30 35 (N NI) ...Its QS 46 5 117 in its underside, which constitutes an extension of the opening 111. A transversely extending wall 118 separates the rear bore 110 from the upper portion of the chamber 116. The wall 118 has openings 120, 121, 122 and 123 extending between the rear bore 110 and the chamber 116. The housing 100 is also formed with a longitudinally extending channel or slot 124 in the bottom of the front bore 104, a pair of parallel, vertical channels 125 (see also FIG. 13) which are located in the insides of the opposite side walls of the handle section 113, a first threaded bore 126 which intersects the front bore 104, second, third and fourth bores 128, 130 and 134 which intersect the counterbore 106. The bores 130 and 134 are threaded while bore 128 is unthreaded. Bore 126, 128, 130 and 134 extend perpendicularly to front bore 104 and front counterbore 106. Bore 126, 128, 130 all intersect an elliptical recess 132 formed in the bottom of housing 100. Vertical bore 134 has a counterbore 136. Another threaded bore 137 intersects rear bore 112 at right angles. Bore 137 has a counterbore 138 (Fig. 1). Another threaded bore 139 in the lower end of handle section 113 intersects irregular chamber 116.

The bore 139 has a tapered counterbore 140 (Fig. 2). A threaded bore 175 (Fig. 2B) extends through the housing 100 and intersects the forward bore 104.

According to Fig. 1, a rear cover 141 and a resilient handle 142 are attached to the housing 100. The rear cover 141 is attached to the rear end of the housing 100 so as to close the bore 110. The cover 141 is connected to the housing 100 by means of a bayonet coupling. More particularly, the latter has in the counterbore 112 a plurality of mutually spaced raised segments 115 (Fig. 2), which cooperate with similarly spaced segments 154 (Fig. 10) on the inner end of the housing 141, so that the cover and the housing can be locked or unlocked by simply rotating the cover relative to the housing. The inner cylindrical surface 143 of the housing mates »få 10 15 20 25 30 35 O\ (JJ h.) "A \O 6 with the rear bore 110 to form a single cylindrical chamber, which is closed at one end by the end wall of the housing 141 and at the other end by the wall 118 of the housing. The housing 141 is releasably locked in place by a screw 144, which is screwed into the threaded bore 137 and projects into a locking hole 119 in the housing 141.

The handle pad 142 cooperates with the handle section 113 of the housing 100 to form a contoured handle or grip which the tool operator can comfortably grasp. The pad 142 has a tongue 150 at its upper end which overlaps a lip 147 on the underside of the housing. The pad 142 closes the openings 117 and 111. The pad 142 has a central strip section 151 which extends into the opening 111 and engages two strips 152 which are located on opposite sides of the handle section 113, thereby preventing relative lateral movement of the pad. The latter is secured in place by a screw 146 which is screwed into the hole 139 and also into a threaded hole 145 in the bottom end of the pad.

The barrel and cylinder assembly 200 is shown in detail in Figures 1 and 3-6. The barrel and cylinder assembly 200 essentially includes a barrel member 202 (Figure 3), a cylinder member 204 (Figures 4, 4a and 5), a support collar 206 (Figure 1) and a hand control 208 (Figure 6).

Referring to Figures 1 and 3, the barrel member 202 has a coaxial bore 200 of circular cross-section throughout its length. The rear end of the bore 210 has a frusto-conical recess 212. The exterior of the barrel member 202 has a first cylindrical region 214 provided with a pair of diametrically opposed bayonet flanges or portions 216, a second cylindrical region 218 of larger diameter, and a third region 219 of smaller diameter than the first region and six similar planes 226 providing a hexagonal cross-sectional shape. The second region 218 is provided with a first pair of diametrically opposed, longitudinally extending grooves 220, a second pair of diametrically opposed, longitudinally extending grooves 222, and a pair of diametrically opposed, circumferentially extending grooves 224, which intersect the grooves 220 and 222. It should be noted that only one of the grooves 220, 222, and 224 is visible in FIG. 3. It should also be noted that the grooves 220 extend past the opposite ends of the cylindrical region 218 to the first cylindrical region 214 and the third hexagonal region 219.

As shown in Figures 1, 4, 4a and 5, the cylinder member 204 has a small diameter tubular projection 228 at its rear end and its generally cylindrical outer surface is chamfered in two areas 229 and 230 to form separate areas 231, 232 and 233. The cylinder member 204 has a coaxial bore 234 which has a first small diameter section 235 which begins at the end of the tubular extension 228, a second section 236 of slightly smaller diameter beyond the remainder of the tubular section 228, a frusto-conical transition section 237, a section 238 of relatively large diameter which extends over the majority of its length, two sections 238A and 239 of even larger diameter, a frusto-conical shoulder 240 and a front recess 241. The outer surface recess 229 extends along less than the entire periphery of the cylinder member 204, resulting in a longitudinal strip 242, which extends between the portions 231 and 232 and has a rear section 224 of considerably greater width. The cylinder member 204 also has an elongated through hole 246 along the ledge 242, which intersects the coaxial bore 234. The ledge 242 also has a pair of narrow, mutually aligned grooves 247 and 248. Another wider groove 249 extends along the ledge 242 and the portion 231. The cylinder member 204 also has a plurality of round ventilation holes 250, which extend radially and intersect the central bore 234. The holes 250 extend at an oblique angle to the central axis of the cylinder member, as best seen in FIG. 4. The central portion 232 4-65 10 15 20 25 30 35. fïí .Lä-g 8 has a plurality of longitudinally extending slots or grooves 252, which intersect the holes 250 at one end and terminate in the beveled sections 230.

Referring to Figures 4, 4A and 5, the front region 233 has two diametrically opposed slots 256. In addition, the recess 241 is chamfered in two areas in line with the slots 256, as shown at 258, and the drill section 239 has a recess at two diametrically opposed locations, which are disposed 90° from the recess 258, as shown at 261. The small diameter tubular extension 228 serves as a cartridge support and for this purpose its end is slotted to form a plurality of fingers 254.

According to Fig. 1, an elastic impact collar 206 is arranged in the cylinder member 204. The collar 206 is cylindrical in cross section and has a peripheral strip 260. The outer diameter of the strip 260 is dimensioned so that the strip fits tightly in the bore section 239 of the cylinder member.

Referring to Figures 1 and 6, the hand guard 208 includes a cylindrical portion 262 having a plurality of longitudinally extending surfaces 272 provided on its outer surface and an end portion 263 having a frusto-conical outer surface. The inner surface of the hand guard is stepped over its length to form a pair of shoulders 264 and 265 (Figure 1). A pair of pins 266 are welded to the inner surface of the hand guard 208 (or molded as an integral part thereof) at diametrically opposed locations. The cylindrical portion 262 is axially slotted a short distance from its rear end, as at 267, and it is also seen that a shallow axial groove 268 in its outer surface is aligned with and extends from groove 267.

The firing pin assembly 300 is shown in detail in FIGS. 1 and 7. It consists of a firing pin member 302, which is formed with a head section 304, and a shaft section 306, which has an enlarged head connection portion 307. A pair of metal retainer rings 308 are arranged in a pair of peripheral grooves 310, which are formed in the head section 304. As shown in FIG. 7, the head section 304 also includes an axially extending blind hole 312 at its rear end, which functions as a combustion chamber. The firing pin assembly 300 is slidably received in the cylinder member 204 in the manner shown in FIG. 1, such that its head section 304 rests in the bore section 238 of the cylinder member 204. The retaining rings 308 are arranged in a tight sliding fit on the inner surface of the cylinder member 204. The shaft section 306 extends through the impact collar 206. The shaft section 306 is undersized with respect to the inner diameter of the impact collar 206. However, the connecting portion 307 of the firing pin is dimensioned so that it mates with the impact collar in a tight sliding fit. The shaft section 306 of the firing pin is long enough to fit in a tight sliding fit in the bore 210 of the type member 202.

The barrel member 202, the cylinder member 204, the striker member 206 and the hand guard 208 are all adapted to be assembled quickly and easily to collectively provide the complete barrel and cylinder assembly 200 in conjunction with the firing pin assembly 300 in the manner shown in Figure 1. The first step is to insert the firing pin member 302 into the cylinder member 204 so that its head section 304 is located in the bore section 238.

The impact collar 206 is then inserted into the cylinder member 204 with its peripheral strip 260 in contact with the surface forming the bore section 239 of the cylinder member 204. The barrel member 202 is then inserted into the cylinder member 204 so that the impact collar 206 engages the frusto-conical recess 212 in the barrel member. When the barrel is inserted, the flanges 216 are first aligned with recesses 258, whereupon the flanges 216 are allowed to move axially into contact with the shoulder 270 formed by the bore section 339 and the recess 241. The barrel is then rotated 90°, whereby it can be displaced into the cylinder member far enough for the flanges 216 to fit in the recesses 261 against the shoulder 240.

At this time, the barrel member is locked against rotation 10 15 20 25 30 35 CR o: ro -rh w 10 relative to the barrel but is free to move axially away from the barrel member. At this time, the barrel and barrel members can also be disengaged by shifting away from each other until the flanges 216 are in the bore 241, at which time the barrel member can be rotated 90° to place the flanges 216 in alignment with the recesses 258, whereby the barrel can be withdrawn from the barrel. After the barrel member 202 has been installed in the barrel member 204, the barrel member 202 is connected to the hand guard 208 by means of a bayonet mounting arrangement, which will be described in more detail below.

For this purpose, a compression spring 269 (Fig. 1) is first inserted into the hand guard 208 until it is received between the shoulder 265 and the pins 266 at the forward end of the hand guard. The barrel member 202 is inserted hexagonal end first into the hand guard 208 so that the forward end of the second cylindrical region 218 of the barrel member is stopped by the pins 266. The cylinder is then rotated to align the barrel member groove 220 with the pins 266 of the hand guard. The barrel is then advanced by pushing the cylinder and hand guard together further into the hand guard against the action of the spring 269 far enough to align the pins 266 with the slots 224, at which point the hand guard is rotated to move the pins 266 into the slots 222. The hand guard and barrel member are then released, allowing the spring 269 to urge the cylinder and barrel assembly to telescope to a degree permitted by the relative movement of the pins 266 in the slots 222. resulting in the barrel being locked to the handguard by means of the pins 266, which are located in the grooves 222, and the spring 269 urging the barrel member and the handguard axially apart. The cylinder member 204 and associated firing pin assembly can then be withdrawn and separated from the locked handguard and barrel assembly by (a) pulling the cylinder assembly axially away from the handguard far enough to bring the flanges 216 into alignment with bore 10 15 20 25 30 35 249 46 CN ll 241, (b) rotating the cylinder a quarter turn so that the flanges 216 align with the recesses 258, and then (c) pulling the cylinder member and the handguard apart.

When the barrel and cylinder assembly 200 is assembled in the manner described above, the barrel member 202 is locked against rotation relative to the hand guard 208, whereby the hand guard and barrel member 202 can perform a telescopic movement towards each other against the action of the spring 269 and the hexagonal end of the barrel member 202 extends through the frusto-conical end of the hand guard 208.

The barrel and cylinder assembly 200 and the firing pin assembly 300 are housed in the housing 100 in the manner shown in FIG. 1. More particularly, and with reference also to FIG. 2, the barrel and cylinder assembly 200 (including the firing pin assembly 300) is positioned in the housing such that the recessed cylindrical portion 229 of the cylinder member 204 is slidably positioned in part in the bore 104 and in part in the counterbore 106, and the cylindrical portion 262 of the hand guard 208 is slidably disposed in the counterbore 106 with the forward end portion of the hand guard 208 and the hexagonal section 219 of the barrel member 202 extending from the forward end of the housing 100. The outer diameter of the cylindrical portion 262 is such that the hand guard fits with a tight sliding fit in the bore 106 of the housing, with the plane 272 serving to form channels between the hand guard and the adjacent interior surface of the housing to permit gases to pass out of the space behind the hand guard. When installing the barrel and cylinder assembly 200 in the housing 100, care is taken to ensure that (a) the slot 267 in the hand guard 208, the grooves 220 of the barrel member 202, and the elongated opening 246 and aligned slots 256 of the cylinder member 204 are aligned with the vertical bores 126, 128, 130 and 134 of the housing, the groove 249 is aligned with the channel 124 of the housing, and (c) the grooves 247 and 248 of the cylinder member 204 are aligned with the threaded bore 175 of the housing (b) the cylinder member 204 (Fig. 2B). 10 15 20 25 30 35 .Iis- CN lb 12 The installation of the barrel and cylinder assembly 200 in the housing requires manipulation of the cylinder stop assembly 400 (Figs. 1 and 8), which serves to limit the extent to which the barrel and cylinder assembly can move back and forth in the housing 100.

Referring to FIGS. 1 and 8, the cylinder stop assembly 400 generally comprises a cylindrical housing 402 having an elliptical flange 403 which fits into an elliptical opening 132 in the housing 100, a cylinder stop pin 404 which is slidably disposed in the housing 402 and has an enlarged knob 406 at its outer end, and a compression spring 408. The cylinder stop pin 404 is shaped to have an upper angled fin 410, a pair of angled projections 411 on opposite sides of the fin 410 and a flange 412. The spring 408 is received between the flange 412 and the knob 406. The spring biases the stop pin such that the fin 410 projects from the upper end of the housing 402.

The cylinder stop housing 402 is mounted in the bore 128 of the housing 100 with its elliptical flange 403 received by the elliptical recess 132. The cylinder stop assembly 400 is secured in place by screws 416 and 418, which are screwed into threaded bores 126 and 130, respectively.

When installed, the fin 410 of the cylinder stop pin 404 extends up and into the housing bore 106 sufficiently to block the insertion of the cylinder member 204 into the bore 104. Accordingly, insertion of the barrel and cylinder assembly 200 into the housing requires that the elongated opening 246 in the cylinder member and the slot 267 of the hand guard be aligned with the stop pin 404 and that the stop pin be pulled out far enough to permit sufficient insertion of the cylinder member to position the rear end of its opening 246 beyond the stop pin 404. The fin 410 is narrow enough to fit in the cylinder member opening 246 but the fin shoulders 411 are just wide enough to not fit in the opening 246 but not so wide that they are prevented from fitting in the slot of the hand guard. 267. When the fin 410 is thus held in its protruding position by the spring 408, the movement of the barrel and cylinder assembly 200 relative to the housing 100 is limited by the length of the opening 246 of the cylinder member 104. If the cylinder stop knob 406 is pulled out with sufficient force to overcome the spring 408, the upper fin 410 can be withdrawn completely from the opening 246 of the cylinder member 204, thereby releasing the barrel and cylinder assembly 200 so that it can be removed by pulling it from the forward end of the housing 100.

It will be appreciated that the engagement of the fin 410 on the cylinder stop assembly 400 with the elongated opening 246 of the cylinder member 204 limits both longitudinal and rotational movement of the barrel and cylinder assembly 200 relative to the housing 100. The same engagement also ensures alignment of the cylinder member groove 249 with the horizontal channel 124 of the housing, alignment of the cylinder member grooves 247 and 248 with the housing bore 175, and alignment of the groove 268 in the hand guard with the screw 420, which is received in the threaded hole 134 and is just long enough to extend into the groove 268. This engagement of the groove 268 and the screw 420 ensures that the hand guide 208 always has its slot 267 aligned with and ready to receive the upper fin. 410 of the cylinder stop assembly 400.

A brake member 425 is disposed in the threaded bore 175 of the housing 100 (FIG. 2B) to provide a limited braking of the movement of the barrel and cylinder assembly 200 within the housing 100. This limited braking is sufficient to substantially prevent movement of the barrel and cylinder assembly 200 during normal handling of the tool, e.g., while carrying it around a work site, but the braking is not so great as to interfere with the intended operational movement of the barrel and cylinder assembly with respect to the housing. The brake member 425 consists of a threaded housing 428, which is screwed into the bore 175, a pin 426, which is slidably mounted in a bore in the housing, a spring 427, which inserts the pin into the bore 104 of the housing 100, and a threaded member 429, which is mounted in the housing so as to hold the spring 427. The forward end of the pin 426 is normally received by one or other of the grooves 247 and 248 of the cylinder member or abuts against a portion of the outer surface of the cylinder member, which extends between the grooves 247 and 248.

The ejector block assembly 500 is disposed in the upper portion of the chamber 116. Referring to FIGS. 1, 9 and 13, the ejector block assembly 500 generally includes an ejector block 502 having a generally rectangular horizontal cross-section, a pair of spring cups 504, a pair of compression springs 506, a pair of steel balls 508, a firing pin housing 510, a pair of alignment pins 512, a firing pin 514 and a firing pin compression spring 516. The firing pin housing 510 is disposed in a rearward extension at 153 of the chamber 116. The ejector block 502 is formed with an internal cavity or chamber 518 extending therethrough from top to bottom, as seen in FIGS. 1, 9 and 13. The ejector block 502 has a pair of opposed slots 520 which form lateral extensions of the cavity 518. The front of the ejector block has an opening 519 (Figs. 9 and 13) which is large enough to receive the cartridge support extension 228 of the barrel member 204. A pair of parallel, horizontal bores 522 and matching counterbores 524 extend from one side of the ejector block 502 into the block and intersect the slots 520. The inner ends of the bores 522 taper spherically to a diameter less than that of the balls 508. The balls 508 and springs 506 are positioned in bores 522 and the cups 504 are secured in the counterbore 524, as shown in Figs. 9 and 13, so that the balls 508 partially engage the slots 520 under the action of the springs 506.

The ejector block 502 also has a tapered bore 526 and a pair of parallel bores 528 extending through its rear surface into the cavity 518. The bores 528 are aligned with a pair of bores 530 in the firing pin housing 510 to thereby receive the alignment pins 512 extending between both the ejector block 502 and the firing pin housing 510 (Figs. 1 and 9). The firing pin housing 510 also has a bore 532 and a counterbore 534 which, when the firing pin housing 510 is engaged with the ejector block 502, cooperate with the tapered bore 526 to provide a chamber for receiving the firing pin 514 and the firing pin compression spring 516. The firing pin 514 is normally located entirely in the aforementioned chamber and, by the action of the spring 516, does not project into the cavity 518 of the ejector block 502. However, by overcoming the force of the firing pin spring 516, the firing pin can be caused to project its pointed end into the internal cavity 518. The ejector block 502 also has a pair of threaded holes 535 and 536 in its rear and a bore 537, which extends all the way through the block parallel to the bores 528.

The ejector block assembly 500 is secured in place in the chamber 116 by a pair of screws, not shown, which extend through holes 120 and 121 in the wall 118 and are threaded into holes 535 and 536 in the block 502. When the ejector block assembly 500 is so secured in the housing 100, the opposing vertical slots 520 in the ejector block 502 are aligned with the vertical channels 125 in the housing 100 (FIG. 13), and also the axis of the firing pin 514 is aligned eccentrically relative to the axis of the cartridge support extension 228 of the cylinder member 204. At the same time, the bore 532 and the counterbore 534 in the firing pin housing 510 are aligned with the opening 122 in the wall 118 of the housing 100 and the bore 537 in the extension block 502 aligns with the hole 123 in the housing wall 118.

According to Figs. 1 and 10, the firing pin mechanism 600 consists essentially of a housing 602 for the firing pin actuator, three compression springs 604, 610 and 618, a detent or wedge trigger 606, a pair of retaining pins 607, 10 15 20 25 30 35 ; s U I PO "m \Û 16 a firing pin actuator 608, a spring retainer sleeve 612, which has an inner front flange 613 and an outer rear flange 615, a retaining ring 614 and a washer 616. The firing pin mechanism 600 is located in the chamber behind the housing 100 between the housing wall 118 and the rear cover 141. The spring retainer sleeve 612 is locked to the rear cover 141 by a retaining ring 614, which is received in an internal groove in the cover 141. The spring 618 urges the washer 616 away from the rear cover 141 and against the flange 613 of the spring retainer sleeve 612. The spring 610 surrounds the outer surface of the spring retainer sleeve 612 and extends into an internal groove 619 in the housing 602. The spring 610 urges the firing pin housing 602 away from the rear cover 141 and against the housing wall 118.

The firing pin actuator 608 is positioned so that its rear end enters the spring retainer sleeve 612 and its shoulder 611 can engage the washer 616 while its forward end extends through a central opening 620 in the actuator housing 602. The actuator 608 is formed with a pair of oppositely positioned recessed flat sides 621, each of which is shaped to provide a flat ridge 622 (only one of which is shown) which ridge has a recess in vertical projection, as shown at 624. The firing pin actuator 608 is designed to fit with a tight sliding fit in a keyhole-shaped opening 626 in the latch 606. The latter is mounted in a transverse opening 627 in the housing 602 and is biased by the compression spring. 604, which is located in a recess 629, which is an extension of the opening 627. The latch 606 is held in place in the opening 627 by two retaining pins 607, which intersect the latch projections 628. The projections 605 of the latch 606 are arranged to slide along the ridges 622 and the recesses 624. The recesses are arranged so that when the projections 605 on the front end of the actuator engage therewith, they will extend slightly beyond the front end of the housing 602, as shown in Fig. 1. 10 15 20 25 30 35 .ß .

The underside of the housing 602 also has a recess, as shown at 631, for receiving the rearward extension 720 of a trigger lever 706, which will be described in detail hereinafter. An axially extending push rod 630 also forms part of the firing mechanism, which is attached to the firing pin housing 602 and extends through hole 123 in wall 118 and through bore 537 in the ejector block 502, as will be described in detail hereinafter. The length of the ridges 622 is dimensioned so that the firing pin actuator 608 can be urged forward by the spring 618 sufficiently for its forward end 632 to extend through the opening 620 far enough to engage and urge the firing pin 514 forward to fire a cartridge located in the cartridge holder 228. If the actuator housing 602 is pushed rearwardly against the cover 141 against the action of the spring 610, the firing pin actuator 608 will also be conveyed rearwardly against the action of the spring 618 by virtue of the recessed portions 624 of the actuator 608 engaging the tabs 605 of the latch. If the latch 606 were to be pushed upwardly into the housing 602 against the action of the spring 604 while the actuator housing 602 compresses the spring 610 to thereby disengage the lugs 605 from the recesses 624, the actuator 608 is released and the spring 618 forces it forward with great force. The firing mechanism 600 is specially designed so that this forward movement of the actuator 608 of the firing pin results in the forward end 632 of the actuator 608 passing through the opening 122 in the housing wall 118 to thereby contact and drive the firing pin 514 forward so that its tip enters the internal cavity 518 of the ejector block 502.

Still referring to Figs. 1 and 10, the housing 602 is arranged to be displaced rearwardly in its chamber in the housing 100 due to its connection with the push rod 630. This rod, which is fixed in the front 10 15 20 25 35 465 249 18 of the actuator 602, is slidably arranged in the opening 123 in the wall 118 of the housing and extends through the bore 537 in the projection block 502 and into the bore 104 so as to be able to engage the rear wall portion 251 of the cylinder member 204 (see Fig. 4a).

The push rod 630 is dimensioned so that when the actuator housing 602 is held in a forward position by the spring 610 in contact with the wall 118 of the housing 100, which is normally the case when no external forces are present, the wall portion 251 of the cylinder member 204 can engage therewith and upon such engagement the fingers 254 at the end of the cartridge support extension 228 will project slightly into the ejector block cavity 518 and the fin 410 of the cylinder stop assembly 400 will be positioned between the two ends of the bottom opening 246 of the cylinder member. At the same time, however, the push rod 630 is dimensioned so that if the projecting hexagonal portion of the barrel member 202 were to be pressed back into the nailing tool with sufficient force to overcome the action of the spring 610, the The actuator housing 602 is forced rearwardly far enough into its chamber to enable the firing pin actuator 608 to effectively engage the firing pin 514 if the latch 606 were subsequently moved to its release position, as indicated above.

The firing mechanism is arranged to move upwardly against the force of the spring 604 to its release position by the trigger assembly 700. Referring to FIGS. 1 and 3, the trigger assembly 700 essentially includes a trigger 702, a trigger push rod 704, a release lever 706, a torsion spring 708, a pin 710 and a pin 712. The pins 710 and 712 have their opposite ends anchored in the side walls of the housing 100 and they extend across the bottom opening 117 (FIG. 2), which is located directly behind and communicates with the cavity 116.

The lever 706 is pivotally mounted on the pin 710.

The torsion spring 708 is mounted on the pin 710 and one end thereof is received by the pin 712 while the other end is received by the pin 706. The spring 708 pushes the lever 706 counterclockwise (with respect to Fig. 1) away from the actuator housing 602. The trigger 702 is slidably mounted in a rectangular opening 703 in the front wall of the handle section 113 (Fig. 2). The trigger push rod 704 has rounded ends with one end located in a rounded recess in the rear extension 711 of the trigger 702 and the other end located in a rounded recess in the lever 706. The push rod 704 connects the trigger 702 to the pin release lever 706, so that the trigger 702 is normally biased to its extended position (Fig. 1) under the action of the torsion spring 708. The forward or extended position of the trigger is determined by engagement of a portion of the trigger with a shoulder 715 of the housing 100 (Fig. 2). When the trigger 702 is pressed rearward with sufficient force to overcome the action of the torsion spring 708, the pin release lever 706 will pivot upwardly toward the actuator housing 602. The various parts are suitably dimensioned so that, when the barrel or cylinder assembly 200 is pressed rearwardly into the housing 100 to an extent permitted by the engagement of the forward end of the cylinder opening 246 with the stop fin 410, thereby forcing the actuator housing 602 rearwardly into the chamber, the actuator detent 606 will be located directly above the extension 720 of the pin release lever 706, so that if the trigger is then pulled rearwardly, the lever 706 will move upwardly far enough for its extension 720 to engage the detent 606. and lift it to the release position to release the actuating member 608.

As can be seen from Figures 1 and 13, the transverse rear extension 711 of the trigger 702 is connected to the trigger by two parallel, spaced apart connecting sections 713, which extend through the chamber 716 adjacent parallel, vertical channels 125. The trigger 702, its rear extension 711 and its connecting sections 713 form an opening for receiving a strip of powder cartridges, as will be described in more detail below.

Such a cartridge strip 802 is shown in Figs. 11 and 12.

The strip is symmetrical and has a plurality of equally spaced step feed slots 804 in both of its side edges. The strip 802 also has a plurality of central openings 808, each in the shape of a cross, for receiving cartridges 810, as shown. The four slots characterizing each opening 808 are sized to receive fingers 254 of the barrel member 204 so that the fingers can engage the underside of the rim of a cartridge while the tapered front portion of the cartridge extends into the barrel extension 228.

The cartridge displacement mechanism 800 serves to displace a strip 802 of cartridges 810, so that the cartridges are sequentially placed in the firing position. The cartridge displacement mechanism 800 is shown in FIGS. 1, 2 and 13 and consists essentially of a belt feed cam 812, a bearing pin 814, a detent 816 and a spring 818. The bearing pin 814 is secured in a hole 815 which intersects the slot 124 in the housing 100. The belt feed cam 812 is located in the channel 124 of the housing and pivots about the pin 814. The cam 812 has an upper cam surface 820 which is generally rounded but has a flat, intermediate section 821. The cam surface 820 is intended to rest in the groove 249 in the cylinder member 204. The rear end of the cam 812 has a finger 822 which extends into the slot 819 (FIG. 13) in the ejector block 502 in position for engagement with the underside of the pawl 816. As the cylinder member 204 swings back and forth in the housing 100, it causes the cam 812 to swing about the pin 814 and thereby alternately raise and lower its finger 822. As can be seen from Figs. 9 and 13, the ejector block 502 has a downwardly directed fin 812 and it also has a narrow slot 819 (Fig. 13) in one side, which continues downwardly into the outer side of the fin 817.

The slot 819 communicates via a vertically elongated opening with one of the cartridge strip guide grooves 520. The latch 816 is located in the slot 819. The upper end of the latch 816 has a pointed finger 824, which extends through the vertically elongated opening and into the groove 520, when it is in its upper position, i.e. the position shown in Fig. 13. The upper end of the spring 818 is located in the recess in the ejection block 502, while its lower end engages an inclined upper edge of the latch 816.

The spring 818 presses the pawl (and cam finger 822) downward. When the cylinder is extended, the cam finger 822 is further down than the position shown in Figs. 1 and 13, as is the pawl 816. The cam finger 822 engages the pawl adjacent its lower left corner. Since the finger 822 is raised, there is also a torsional force on the pawl which presses its finger 824 into the groove 520. Thus, as the pointed pawl finger 824 passes up past the lower limit of the opening connecting the slot 819 with the groove 520, the finger will enter one of the recesses in the cartridge strip 802 which is located in the grooves 820 and cause the strip to be stepped upward. When the cam finger 822 is no longer pushed upward, the spring 818 will cause the pawl to move downward and also cause the cam finger 822 to move with it.

As the pawl moves downward, the angled underside of its finger 824 will cause the pawl to move past the strip, which is held by the detent balls 508. The spring 818 will also cause the pawl to rotate its finger away from the strip, thus allowing the pawl to move more easily down into the slot 819.

It should be noted that the cartridge strip 802, carrying the cartridges 810, can be inserted into the open lower end of the tool handle and into the opposing parallel channels 125 and pushed upward through said opening, which is formed by the trigger members 711 and 713 (Figs. 1 and 13) and into the grooves 520 in the ejector block 502 until one of the step feed slots 804 engages the finger 824 of the ratchet 816. Thereafter, each time the cylinder member 204 moves forward and backward in the housing 100, the cam 812 will pivot to raise and lower its finger 822, which in turn causes the finger 824 of the ratchet 816 to move downward and upward, respectively. upward. Due to the angled underside of finger 824 and the engagement of steel balls 508 of ejector block assembly 500 with step feed slots 804 in the opposite edge of strip 802, each combined forward and then rearward movement of cylinder member 204 will advance cartridge strip 802 one step. The various members are suitably dimensioned so that each advance causes a new cartridge to align with cartridge support projection 228 on cylinder member 204. In this position, the axis of cartridge 810 is slightly below the tip of firing pin 514, thus enabling edge firing of the cartridge.

The operation of the fastener driving tool will now be described.

Starting from the tool in its "rest" position, i.e., in which position the tool is in the condition shown in FIG. 1, the tool is prepared for use by inserting a cartridge strip 802 into the nail gun in the manner previously described, whereby a cartridge 810 is located in the ejection block 502 aligned with and immediately behind the cartridge support projection 228. A nail assembly 900 comprising a nail 902 engaged with a resilient, finned nail holder 904, as shown in FIG. 14, is then inserted into the forward end of the central bore 210 of the barrel member 202. The nail holder 904 serves to keep the shank of the nail 902 aligned in the bore 210 of the barrel member 202 and also provides sufficient friction with the surrounding walls of the barrel member 202 to hold the nail in place when the nail gun handled. At this point the tool is in the "ready state".

However, if the operator at this time actuates the trigger of the tool without any further input 10 15 20 25 30 35 23, nothing will work. The reason for this is that the actuating housing 602 is at this time held in its forward position by the spring 609 in engagement with the wall 118 of the housing 100, which results in the pin release lever 706 being blocked by the underside of the actuating housing, so that it cannot activate the firing mechanism 600 to drive the firing pin 514 forward into contact with a cartridge 810.

Similarly, if at this time a tool operator were to grasp the hand guard 208 and pull it rearward toward the ejection block 500 and then actuate the trigger, the actuating housing 602 would be maintained in its forward position and again nothing would happen.

The reason for this is that when the hand guard 208 is pulled rearward, it can displace the cylinder block until the force of the springs 610 and 618 exceeds the force of the spring 269, whereupon the rearward movement of the cylinder would stop and the hand guard would simply slide rearward against the action of the spring 269 until the end of the hand guide is stopped by engagement with the shoulder 108 of the housing 100. The spring force of the springs 610 and 618 is sufficient to stop the rearward movement of the cylinder member in the housing before the detent 606 aligns with the extension 720 of the trigger lever 706. As a result, the trigger 702 cannot cause the firing mechanism 500 to drive the firing pin 514 forward into contact with the cartridge 810.

However, if the tool is in the "ready condition", i.e. with the cylinder in the position shown in Fig. 1 with the front end of the barrel member 202 positioned against a workpiece and the tool pushed forward to be placed in the "firing condition", and the trigger 702 is depressed, the tool will be fired. The reason for this is that by pressing the tool against a workpiece it is brought into the firing position, whereby the barrel and cylinder assembly 200 slides rearwardly within the tool far enough for the cylinder member 204 to receive the cartridge 810 in its cartridge carrier extension 228 and at the same time, by means of the push rod 630, the actuating housing 602 is pressed to its rear firing position, where its detent 606 aligns with the projection 720 on the lever 706. During this operation, the firing pin member 302 is displaced rearwardly with the cylinder member 204 due to the tight engagement of its retaining rings 308 with the inner surfaces of the cylinder member. If the trigger 702 is now actuated, the pin release lever 706 will move upward and in turn press the latch 606 upward and thereby release the firing pin actuating member 608, so that it moves forward under the action of the spring 618 and thereby drives the firing pin 514 into edge contact with the cartridge 810.

This fires the cartridge 810 in the cartridge position. The resulting hot combustion gases flow into the interior of the barrel member extension 228 and into the combustion chamber 312 of the striker member 302, thereby propelling the striker member 302 forward in the barrel and cylinder assembly 200 into contact with the nail assembly 900, thereby propelling the nail assembly 900 out of the barrel member 202 and into the workpiece. When this occurs, the hot combustion gases behind the stop member 302 pass substantially completely along the interior of the cylinder member 204 until they reach the ventilation holes 250. The gases flow out through the ventilation holes 250 along the grooves 262 in the cylindrical portion 232 of the cylinder member and then expand to the area between the outer section 230 of the cylinder member 204 and the interior of the hand guard 208. From there, the gases flow along the grooves 256 in the barrel member 204 and enter the groove 220 of the barrel member 202. The gases then exit the tool via the spaces between the hexagonal outer surfaces 226 of the barrel member 202 and the circular inner surfaces of the hand guard 208. It will be appreciated that by keeping the slot 267 in the hand guard 208 as short as possible, if present at all, the gas can exit the tool via this slot. For this reason, the slot 267 is of such a length that it does not extend past the screw 420 when the tool is fired. As a result, the tool utilizes the explosive force of a cartridge 810 with greater efficiency for driving the striker member.

The forward movement of the stop member 302 should normally be stopped when its forward end engages the workpiece, but if the workpiece does not stop the forward movement of the stop member (e.g., in the case of softwood), the engagement of the head section 403 with the impact collar 206 will stop the forward movement of the stop member 302. In both cases, the forward movement of the stop member 302 is stopped before its head section 304 can engage the upper fin 410 of the cylinder stop member 404.

The tool is prepared for a new firing in the following manner. First, the tool is lifted out of engagement with the workpiece and then the barrel and cylinder assembly 200 is brought out of contact with the spent cartridge 810 and brought forward to the limit of the opening 246 either by pulling the hand guard 208 forward or by "throwing" the tool forward with a flick of the wrist. By this action, the stop member 302 is caused to return its head portion 304 to engage the rear portion of the cylinder member 204 since the cylinder member 204 is moving forward in the housing 100 and the stop member 302 will be blocked from further forward movement by engagement of its head portion with the fin 410 of the cylinder stop assembly 400, so that the two parts once again assume the position shown in FIG. 1 relative to each other. At the same time, the movement of the barrel member 204 in the forward direction in the housing 100 will allow the cam member 812 to pivot about the pin 814, whereby the spring 818 causes the latch 816 to fall downward into the slot 819 to engage another groove 804 in the cartridge strip 802. The barrel and barrel assembly 200 is returned to the position shown in FIG. 1 by pulling back on the hand guard 208. As the barrel and barrel assembly 200 is returned, the stop member 302 moves rearwardly thereby due to the engagement of the retaining rings 308 with the interior of the barrel member 204. The return movement of the barrel and cylinder assembly 200 causes the cylinder member 204 to reengage the push rod 630. At the same time, this return movement of the barrel and cylinder assembly 200 causes the cam member 812 to once again pivot on the pin 814, thereby driving the latch 816 upward and thus stepping the cartridge strip 802 upward, thereby displacing the spent cartridge and bringing a new cartridge into position adjacent the firing pin.

The fastener driving tool has now returned to its "ready state" as previously described.

Subsequent firings are carried out by repeating the above operation.

The powder-powered tool for driving fasteners as described above offers a number of advantages compared to previous devices.

Firstly, the tool is mechanically simpler than many of the previously known magazine-type tools, which is why it is cheaper to manufacture, easier to assemble and more reliable to use.

Secondly, the described tool is provided with improved exhaust passages for venting hot combustion gases from the interior of the tool, which is why it is quieter, has less recoil, is more energy efficient (and therefore more powerful) and has less tendency to jam due to a build-up of spent powder residue in the interior of the tool.

Thirdly, the tool can be used with cartridges with so-called "red charge" and light fasteners while the tool is still a "low-speed tool".

Fourth, the tool can be easily disassembled in the field to facilitate inspection. In this regard, it should be noted that the entire barrel and cylinder assembly 200 can be withdrawn from the housing simply by pulling the stop button 406 of the cylinder stop assembly 400 and the entire trigger assembly 700 can be exposed by removing the screw 146 in the bottom of the handle section and pulling off the hand grip 142. Removal of the trigger 702 is easily accomplished by withdrawing the trigger push rod from the location between the trigger and the release lever 706 and sliding the trigger rearwardly from the handle section. In addition, the firing mechanism 600 can be withdrawn from the housing 100 simply by unscrewing the screw 104 from the back of the housing and the rear cover. l4l is removed from its bayonet mount on the housing.

Fifth, the described tool can be used to drive fasteners of different types and dimensions (e.g. nails, eye bolts, threaded studs, etc.) simply by removing the barrel and the stop member and replacing it with another barrel and another stop member, which have different dimensions.

Sixth, the described tool can be readily adapted for use with a superior bar assembly to thus form a superior bar tool, as will be apparent from the following section, whereby modifications of the invention are described.

Seventh, the described tool employs an improved trigger assembly which is simple, relatively inexpensive to manufacture and does not cause the tool to jam. In some known tools, it is difficult to remove a cartridge strip which has become jammed as a result of faulty manufacture or installation in the tool or incorrect use of the tool. The improved trigger assembly helps to reduce such jamming and also facilitates the removal of a strip which may have become jammed.

.Eighthly, the described tool employs an improved cam arrangement in the cartridge displacement mechanism in the form of a flattened portion of the upper end of the cam to minimize cam wear and reduce maintenance and tool chipping. In addition, the groove 249 in the cylinder assembly ensures that the cam 812 properly engages the cylinder member and facilitates preventing rotation of the cylinder within the housing 100.

It should also be noted that the cover 141 is so locked to the sleeve 612 that these members plus the spring 618 and the washer 616 form a single subassembly. Thus, when the cover 141 is removed from the housing 100, the sleeve 612, the spring 618 and the washer 616 are removed. A modification of the invention will now be described.

As previously noted, the powder-actuated nail-driving tool is intended to be used by a tool operator who grasps the tool around the handle portion of the housing with one hand and then activates the trigger member 702 with the index finger of that hand. However, it may be desirable to use the nail-driving tool in locations that are difficult to reach, such as in ceilings, and in that case the tool is modified to accommodate a rod assembly 950 having a remotely operated trigger mechanism, as shown in Figs. 15-17.

According to Figs. 15A and 15B, the tool shown in dashed lines A is identical to the previously described powder-actuated tool except that the rear cover 141 of the original tool has been replaced with a new rear cover 141a, which is intended to facilitate attachment of the rod assembly 950. The cover 141a corresponds to the cover 141 except that it has a hollow, cylindrical extension of the collar 952 at its rear end dimensioned to receive therein one end of a rod member 954, which is part of the rod assembly 950. The rod member 954 is fixed to the cylindrical extension 952 by means of a pin 956, whereby the tool is firmly attached to the end of the rod member 954.

The rod member 954 is hollow for slidably receiving a power transmission assembly 960. The rod member 954 has a side opening 962 adjacent the extension 952 to allow a portion of the power transmission assembly 960 to extend from the rod and be connected to the trigger 702. The power transmission assembly 960 has a solid rod 966 having a yoke 968 attached to its forward end. The yoke 968 is slidably received in a guide collar 969 attached to the rod. The fork-shaped end of the yoke 968 is pivotally attached to a right- and left-hand type screw coupling, which consists of a first coupling member 970, which has a threaded hole into which the threaded end of a second coupling member 972 is screwed. The latter coupling member in turn has a threaded hole into which the threaded end of a trigger actuator member 974 is screwed. The screw connection between the coupling members 970 and 972 is right-handed while that between the coupling member 972 and the actuator member 974 is left-handed. As a result, rotation of the coupling member 972 in one direction will bring the actuator closer to the coupling member 970, with rotation in the opposite direction separating these parts. A lock nut 976 on the coupling member 972 is used to lock the two members together. The actuator member 974 has a hooked end 978 and is shaped so that its hooked end is hooked around the front of the screw coupling, thereby ensuring that if the power transmission rod 966 is axially displaced in the rod member 954 away from the end cap 141a, the trigger member 702 will be pulled back to the firing position by the trigger actuator member 974.

According to Figs. 15B and 17, the power transmission assembly is slidable towards and away from the end cap 141 by means of a cam arrangement. More specifically, the rod 966 is screwed into an insulated plastic pull rod 980 which is pivotally connected to the forked end of the cam follower 983 by means of a bearing pin 982. The pull rod 980 has an elongated hole 984 in which a guide pin 985 is received which extends transversely of the rod 954 and is attached to the handle stop collar 998. The pin 985 locks the stop collar to the rod. 10 15 20 25 30 35 (sxl \O 30 The cam follower 983 has a cylindrical section 986 of reduced diameter, which section has a diametrically extending bore 987 (Fig. 17), which receives a cam follower pin 988 (Fig. 15B). The reduced diameter section 986 of the cam follower fits with a suction fit in a hollow portion of a cylindrical cam 989 in the rod 954. The hollow portion of the cam 989 has two cylindrically opposed holes 990 with a spiral contour in its side wall to receive opposite end portions of the pin 988. The length of the pin 988 corresponds to or is slightly less than the outer diameter of the cam 989. Preferably, the pin 988 is free to slide axially in the bore 987 and its ends are rounded so as to facilitate movement relative to the inner surface of the rod. The cam 989 is attached to a cylindrical handle 991, which rotatably surrounds the rod 954 by means of a pin 992. The latter extends through a hole 993 in the rod 954, which is elongated peripherally over an angle of approximately 900 so as to permit rotation of the handle a quarter turn relative to the rod. The cam 989 has a section 994 of reduced diameter, which section is surrounded by a torsion spring 995.

One end of the spring 995 is anchored in a slot in the cam 989 while its other end is screwed into a 996 in the side wall of the rod 954.

The spring 995 biases the cam so that the cam pin 988 normally rests in the ends of holes 990 which are closest to the cam follower 983, so that the gap 999 extends therebetween, as shown in Fig. 15B. The left and right coupling is adjusted so that when the gap 999 is present, the actuator will be close to but not exert any pressure on the trigger member 702. However, if the handle 991 is rotated relative to the rod 954, the pin 988 will engage the holes 990 to thereby reduce the gap 999 and the power transmission assembly 960 will move away from the rear cover 141 and thereby press the trigger member 702. Thus, if a cartridge is placed in the firing block in the firing position and the handle 991 is rotated approximately a quarter turn while the barrel of the tool 10 15 20 463 25%) 31 is pressed against an interior ceiling, the rotation of the handle will cause the tool to fire the cartridge and thereby drive a nail into the ceiling.

It will be appreciated that the rod assembly 950 can be manufactured in various lengths depending on the job at hand. In all circumstances, firing the tool by twisting the handle is advantageous in that the operator can grasp the handle and the rod to press the tool against a workpiece overhead. The twisting operation also reduces the risk of inadvertent firing of the tool. In addition, the rod assembly is free of protruding external parts that could cause injury. Prior art rod assemblies are typically operated by bicycle handbrake type levers which can easily be inadvertently actuated. It should be noted that for reasons of cost and strength, the rod assembly components are manufactured from metal, such as aluminum and steel. However, the rod 954 and the insulating member 980 are manufactured from plastic to facilitate electrical isolation of the trigger actuating member from the cam assembly.

Claims (14)

., | T> 10 15 20 25 30 Üx 32 PATENTKRAV Gunpowder driven tool for driving fasteners, comprising (a) a housing (100) having a first opening, (b) a spout and cylinder assembly (200), which is located in the first opening and arranged in front and reciprocating movement in the housing (100) and comprising a hollow barrel (202) and a hollow cylinder member (204) having first and second longitudinally extending grooves (246, 249), the barrel (202 ) is so mounted on the cylinder member (204) that the two members act as a single unit, (c) a stop assembly (300) slidably mounted in the barrel and cylinder assembly (200) and reciprocating therein, (d) ) a cylinder stop assembly (400) having a projecting member (402) which normally extends into the first groove in the cylinder member (204) so as to limit the longitudinal movement and the rotational movement of the barrel and cylinder assembly (200) relative to the housing (100) , (e) an ejection block assembly (500) mounted in the housing (100) and h is a projection block (502) having a longitudinally extending bore and a central chamber, and an impact pin (514) resiliently mounted in the projection block (502) for penetrating the central chamber when a suitable force is exerted thereon, (f) a firing mechanism (600), comprising a percussion actuator (608), a movable member (602) slidably supporting the actuator (608), a spring device (610) which actuates the actuator (608) and the movable the means (602) against the projection block (502), a locking means (606) releasably locking the actuating means (608) at the movable means (602), and a push rod (630) which is attached to the movable means (602) and extends through the bore of the ejection block (502) 10 15 20 25 30 35 ro IE »4633 33 into contact with the barrel and cylinder assembly (200), so that movement of the barrel and cylinder assembly (200) in the housing (100) towards the extension block (502) causes the push rod (630) to shift moves the movable member (602) away from the ejection block (502) so as to store energy in the spring device (610), which can thereby propel the operating member (608) forward towards the striking pin (514), when the locking member (606) released from the actuator (608), (g) a trigger device (700) for actuating the detent means (606) and (h) a cartridge displacement mechanism (800) comprising a cam (812), a detent hook (816) and a spring (818 ) and which is arranged to displace a cartridge belt so as to place a cartridge in firing position next to the cylinder means (204) and the striking pin (514), as the barrel and cylinder assembly (200) reciprocate, characterized in that the trigger device ( 700) consists of a release lever (706), a first pin (710) which rotatably supports the release lever (706) for movement towards and from the firing mechanism (600), a torsion spring (708) which is coupled to the release lever (706) and a second pin (712) so as to resiliently actuating the release lever (706) away from the firing mechanism (600), a trigger (702) and a trigger push rod (704), which connects the trigger (702) to the release lever (706) so as to cause the trigger (702) to push the release lever (702) 706) in the direction of actuation of the locking means (606), when the trigger (702) is actuated, whereby the actuating means (608) for firing is caused to drive the percussion pin (514) forward for firing a cartridge located in line with the cylinder means (204). Tool according to claim 1, characterized in that the cylinder means (204) consists of first, second and third raised cylindrical portions (231, 232, 233), of which the first portion (231) is arranged at the cylinder means ( 204) one end adjacent the ejection block assembly C.) \ CN 10 15 20 25 30 35 l \ 3 lo 34 (500), the second portion (232) is arranged around the center of the cylinder member (204) and the third portion (233) is arranged at the opposite end of the cylinder means (204) at a distance from the ejection block assembly (500), the third portion having means (256) for conducting gases around the barrel (202). Tool according to claim 2, characterized in that the cylinder member (204) has a longitudinal strip (242) extending between the first and second cylindrical portions, which strip has a rear section (244) of considerably increased width, and that the first groove (246) is arranged in the longitudinal strip while the second groove (249) is arranged in the rear strip section. A tool according to claim 3, characterized in that the second cylindrical portion of the cylinder member (204) has a plurality of holes (250) extending at an acute angle relative to the longitudinal axis of the cylinder member (204) and leading to the cylinder member (204). 204) internal for venting gases formed during firing of a cartridge by the firing mechanism (600). characterized in that the second cylindrical member of the cylinder member (204) The tool of claim 4, the portion having a plurality of grooves (252) communicating with the holes and extending along the second cylindrical portion toward the third cylindrical portion so as to conduct gases vented by the holes toward the front end of the barrel (202). A tool according to claim 1, characterized in that the barrel and cylinder assembly (200) has a hand guard (208) having a substantially cylindrical portion with a slot (267) aligned with the first groove. and has a length which is limited so as to prevent any significant gas release via the slot. 7. A tool according to any one of the preceding claims, characterized in that the firing mechanism (600) has a support means (602) for the percussion actuator (608) which support means is slidably mounted in a support chamber in the housing and slidably supports the percussion actuator 10. 25 30 35 4> Ch 04 RJ 3- \ 9 35 (608), which support chamber has an end wall (118), which separates the support chamber from the percussion pin housing, first spring means (610), which actuate the operating means (608) against the end wall , second spring means (618), which actuate the actuating means (608) for the percussion pin for movement towards the end wall relative to said support means (602), and a spring device, which normally presses the locking means (606) to the locking position. A tool according to any one of the preceding claims, characterized in that the barrel (202) has a mouth end and the cylinder means (204) has openings (250) for venting gases obtained by firing a cartridge by the percussion pin, which openings are arranged around the cylinder member (204) in a radial arrangement and each opening is inclined so as to direct gases towards the mouth end of the barrel (202). A tool according to any one of the preceding claims, characterized in that the spout and cylinder assembly (200) has a hand guard (218) having a substantially cylindrical portion with a slot (267) and a groove abutting the slot. (268), wherein the slot and the groove are aligned with each other and the groove ends shortly before a second substantially truncated conical portion. A tool according to any one of the preceding claims, characterized in that the outer surface of the barrel (202) has flat sections (226) which form gas passages between the barrel and the hand guard. A tool according to any one of the preceding claims, characterized in that the actuator (608) has two strips (622) each with a groove (624) and that the locking means (606) surrounds the actuator (608) and has two projections ( 605), which engages with the grooves as long as the trigger is not affected. A tool according to any one of the preceding claims, characterized in that the trigger (702) has a rear section (711) formed with a first round recess, that the lever (706) has a second round recess and that the push rod (704) of the trigger (702) forms -R- 10 15 20 25 CN ro to 36 a rod with rounded ends, which are placed in said first and second recesses and are held there by the force which the torsion spring (708) exceeds on the lever. A tool according to claim 12, characterized in that the latch is received in a cavity characteristic - in the support means (602) of the operating member (608) and that the latch spring means (604) presses the latch in a direction which keeps the lugs thereon in contact with the lists. A tool according to any one of the preceding claims, characterized in that a rod assembly (950) is attached to the housing (100) for operating the tool and causing the trigger (702) to actuate the firing mechanism (600), which rod assembly comprises a hollow rod having first and second opposite ends with the first end connected to the housing (100), a trigger actuating means (907) engaging the trigger (702), a power transmission mechanism (960) which is coupled to the trigger actuator and extending in the rod, means (970) connecting the force transmitting mechanism to the trigger actuator, a handle (991) rotatably mounted on the rod at its other end, and cam means (989) connecting the handle to the force-transmitting mechanism for causing it to actuate the trigger when the handle is rotated relative to the rod.