SE460586B - DEVICE FOR NIPPING OF CONSTRUCTION PARTS - Google Patents

Abstract

A device for nailing together two construction elements 7, 8 by a nail being pressed by means of a first pressure medium cylinder 5 through the one construction element, for example a plasterboard 7, and further into the second construction element, for example a wooden transom 8. The first cylinder 5 is secured in an axially movable manner to a stand part 1 and a pressure foot 6 is adjustably fixed to the cylinder by means of which a collaring force can be generated against the construction. The working stroke of the piston rod 20 of the first cylinder realizes the forcing home of the nail. A second, smaller pressure medium cylinder 3, fixedly connected to the stand part 1, is set up to collar the first cylinder and its pressure foot tightly against the construction elements so as to hold these together as the nail is forced home. The second cylinder 3 is arranged such that its piston rod 12 is displaceable in a direction essentially perpendicular to the motional direction for the piston rod 20 of the first cylinder. Fixed to the free end of the piston rod 12 of the second cylinder is a wedge 4, which can be driven in between the rear part 23 of the first cylinder and the stand part, for realizing the collaring of the first cylinder, with constant collaring force, and maintained bearing of the pressure foot against the construction elements, even when the parts are locally further pressed together as the nail is driven in.

Description

sin .. li * "'*' L ~ '-« ~ - ~... n? _;: inf -.> s' ._. H1. _ «1.3 1-1 ... êljglaqav, šå§lel , _j_z¿wf-, gp, l4eo šss' 10 15 20 25 30 35 especially the gypsum board, which may not be loaded with a greater force than say a maximum of 50 kp.

In order to achieve both such a limited holding force and the significantly greater nail driving force, different methods can be used.

One possible solution would be to use two different pressure media cylinders operating in the same direction: one to achieve the smaller holding force and the other to achieve the significantly greater nail driving force.

The two cylinders can either be arranged separately next to each other or form a double cylinder, where one cylinder is coaxially arranged inside the other.

In the first case, one has the disadvantage of two cylinders which require more space laterally than a single cylinder requires, and which also give the effect of force at different places; in both cases, there is still a risk that the gypsum board / latch is exposed to a maximum holding force that is greater than the holding cylinder's own maximum force. The object of the invention is to - when nailing together such structural parts of which at least one has only limited strength - avoid the above-mentioned disadvantages which pertain to the known construction solutions, and instead offer a new type of nailing device, with which part can be achieved cohesion of the structural parts by means of a smaller, substantially constant holding force, and on the other hand nail pressing by means of a larger driving force exerted on the nail head only.

According to the invention, said object is achieved in a device of the type indicated in the introduction in that a second linear motor, fixedly connected to the frame part, in the form of a smaller pressure medium cylinder, for example a second compressed air cylinder, is arranged for close application of the 30 35 Û '._ easoisas * UI first cylinder and its presser foot not the construction parts. to keep the truth of these when nailing. which second cylinder is so arranged that its piston rod is displaceable in a direction substantially perpendicular to the direction of movement of the piston rod of the first cylinder. and that at the free end of the piston rod of the second cylinder a nellan of the first cylinder notch frame part is fixed. the rear part and the frame part actuate wedge for effecting the attachment of the first cylinder down substantially constant attachment force and maintaining the presser foot abutment not the construction parts even in the case of local further compression of the parts during nail drive.

The actuating force produced by the presser foot of the first cylinder. son holds the construction parts together when the nail is pressed. was thus produced by the force action of the second cylinder via the wedge and its' power exchange 'is 90' elongated and reinforced in the direction of engagement not the construction parts. In practice, it should generally be obligatory for the larger one. the first cylinder and the lower one. the second cylinder is compressed-air cylinders. Due to the fact that the force action of the first cylinder 'lies on' the wedge during the presser foot application and the actual nail drive stroke, it is achieved that a post-adjustment of the presser foot application force takes place all the time so that this force is kept constant even during the local further compression of the structural parts. the piston stroke of the first cylinder achieves the nail drive. The wedge-cylinder mechanism at the device is thus pleased to accommodate such variations in the axial position of the presser foot and down which the axial position of the first cylinder may occur during the actual nail drive. This is significant since a close application of the presser foot not the construction parts during the entire nail driving stroke is a prerequisite for the nail to be driven to the exact set depth during the working stroke. In practice, this usually means that the nail head is driven in so far that it is slightly sunk below the surface of the upper structural part. 10 15 20 25 30 35 460 šseß '. m; »Fb? - In practice, the driving force is transmitted from the piston rod of the first cylinder to the nail head via a so-called so-called piston rod end. driver. son constitutes axial extension to the piston rod- enb To achieve accurate. controlled movement and power transmission from the wedge to the rear part of the first cylinder, it is advisable that there is an outwardly open guide groove for the wedge in it. which groove has a flat bottom surface whose normal direction forms an acute angle with the direction of movement of the piston rod of the first cylinder. which acute angle corresponds to the wedge angle of the wedge.

The first cylinder may suitably have a cylinder housing with a prismatic outer shape, for example down the shape of a steering wheel block. in which cylinder housing the cylindrical barrel of the reciprocally reciprocating piston rod piston is usually located. In the rear end of the cylinder, the cylinder cover is suitably attached to the rear end of the barrel, in which the guide groove for the wedge is formed.

The front part of the cylinder housing is obligatory to have a guide sleeve projecting from the present cylinder housing wall within which the piston rod runs.

In order to provide a changed countersink depth for the nail hood - with regard to the upper upper part of the construction part in question - it is suitable for the presser foot to have a device which can be arranged axially adjustably on the guide sleeve. preferably with a side nose nail working tool nose. which is employed note the construction parts at the nail drive. The immersion depth is independent of the dimensions of the current pair of structural parts. son should be nailed together. Especially when the uppermost structural part is a gypsum board, it may be obligatory for the abutment part of the tool nose to be an annular lug which distributes the application force over a relatively large annular surface area of the gypsum board.

The second cylinder and the wedge can per se be attached directly to the frame part resp. run directly along the surface of the stand- 10 15 20 25 30 35 v f '_ ~~ L' i ff; u '- q> - y; .. .i _ _ L *: _. v _ _, - -'_. »_ 1.15; J 'W f * f ”f' f- ^ n” delen. but in practice it would be most suitable for the second cylinder to be attached to a mounting plate arranged on the frame part, on which side a side V is guided a pair of parallel guide rulers with which edge guide flanges on opposite sides of the wedge are in sliding guide engagement. Rärigenon simplifies the installation of the second cylinder and the wedge truly facilitates the replacement of these two parts in the event of, for example, wear. The wedge is furthermore suitably connected to the first cylinder by means of a control PP arranged perpendicularly to the longitudinal direction of the guide rafter. which is attached to the rear part of the cylinder and extends across the guide rafter at a distance from and parallel to its bottom surface. The guide pin then extends through an elongate. in the wedge a guide slot is formed which runs parallel: ed the side of the wedge adjacent to the barrier bottom.

The first cylinder is thus 'suspended' at the mounting plate via the guide pin in the rear part of the cylinder and the guide pin receiving wedge son runs along the mounting plate or the guide rulers attached thereto through which the wedge constantly pours the adjacent groove of the mounting plate.

The working stroke of the piston of the first cylinder and thus the length of the nail indentation are suitably determined by axially spaced end position stop means in the cylinder. These end position stop means are most easily constituted on one side by the inside of the cylinder head. and on the other side inside the cylinder housing end wall passed through the piston rod.

The starting force produced by the device according to the invention will of course depend on the wedge driving force produced by the second cylinder. partly by the force reinforcement provided by the wedge in the axial direction of the first cylinder. The force reinforcement on the other hand depends mainly on the wedge angle of the wedge. In practice, it has been found most suitable that the wedge angle has a value in the range between 10 'and 20'. preferably in the range 12'-16 '. If one chooses a t _W_ _¿U, ílh41ñFr¶ši8I; .¶Af¿i? 10 15 20 25 30 35 460 5 \ 86. a ..., ... en, _. .,., ~.-..._.._. ».__. _ _., ¿_.-,;., Haga. L ... a wedge angle of say 14 'and counting down a friction number in the interval 0.07-0.08 (son grille for normally ground steel) so you can count on the first force of the first cylinder against the structural parts being 1.5 a 1.6 times greater than the wedge driving force of the second cylinder.

The second cylinder suitably has - like the first cylinder - a prismatic cylinder housing with a square or rectangular cross-section. This simplifies the mounting of the cylinder housing at the mounting plate on the frame part. Because the cylinder housings will then have a large wall thickness in the longitudinal ones. the angular corner portions, so offers the possibility to easily set up the required pressure medium channels in these portions for the supply or working surface. removal from the working chambers of the cylinders. The invention will now be further described and explained below with reference to a preferred embodiment shown in the accompanying drawings.

The following applies to the drawing figures: Fig. 1 shows a partial vertical section through a device according to the invention with two structural parts arranged below which are to be nailed together; Fig. 2 shows the cylinders and the wedge seen from above at the section line ll-ll in Fig. 13 Fig. 3 shows a vertical projection at the section line lll-lll in ng. 1: 'Figs. Aa and 4b show the cylinder head of the first cylinder seen in axial cross section resp. horizontal projection from above; and Figs. Sa and Sb finally show kilos seen in side view resp. from above in horizontal projection. 'ff-fr' ”va” _l__ íw fl »V., -«.-__-; - NW ”É" ”'^ í"' "f '” ”lå” ..-_ ¿, ~ V, .- Fig. 1 shows the device according to the invention mounted under a horizontal frame part 1. The device comprises four main parts or components, namely one on the underside of the frame part. l fixed horizontal mounting plate 2. a horizontal compressed air cylinder attached to the mounting plate 3. a wedge 4 offset at the underside of the mounting plate 2 and a vertical compressed air cylinder 5 supported by the wedge with a presser foot arranged at the bottom 6. The presser foot 6 is intended to movement of the cylinder 5 is brought into contact with a pair of structural parts 7. 8 in order to compress them before the actual nail drive during the nailing of the parts.In the example shown, the structural part 1 is assumed to be a horizontally arranged gypsum board, while the part 8 is a wooden bar Parts 7 and 8 are placed on a fixed horizontal surface 9.

The horizontally arranged. the smaller compressed air cylinder 3 comprises a cylinder housing 10. a reciprocating piston 11 and a piston rod 12 mounted therein and the outer free spirit of which is fixed in the wedge 4. The right spirit of the cylinder 10 is closed by means of a lid 13.

The wedge 4 is supported by the fixed plate 2 in that the wedge at the top has a pair of laterally projecting edge guide flanges 11 running on oppositely directed edge flanges 1S of a pair of parallel guide rulers 16 screwed onto the underside of the fist plate 2.

The vertically aligned larger compressed air cylinder S comprises a cylinder housing 17 with lower end wall 18. and a piston 19 with associated piston rod 20 lowered and reached in the barrel housing and the associated piston rod 20. The piston rod 20 projects out of the cylinder housing 17 through an opening in the cylinder end wall. the wall is guided in a guide sleeve 21 projecting from it. At its rear. in the upper end part of the drawing, the cylinder housing 17 is closed by means of a cylinder cover 23 attached to the upper end of the cylinder bore 22. 460586 ß ... 10 15 20 25 30 35 fÅ¿o §sei. ... and Yes. s: _ -_ * Tf-ll 'i In the cylinder cover 23 of the cylinder 5 there is an upwardly open guide groove 24 for the wedge 4. The guide groove has a flat hot surface 25 which forms the angle a down the horizontal end surface 26 of the cylinder cover and extends parallel to the adjacent underside of the wedge 4 27. For further study of the cylinder head 23 and the wedge 4, reference is made to Figures 4a. 4b resp. Sa. Sb which shows these parts on a larger scale.

As can be seen from Fig. 2 and Fig. 4b, the cylinder S has a prismatic cylinder housing 17 with a square cross-section. the cylinder 3 also has a linkably square cross section. As can be clearly seen from Fig. 4b, the guide groove 24 extends across the end face of the cylinder head parallel to its opposite side surfaces 28 and 29. The guide groove 24 is thus defined laterally by a pair of opposite flange portions 30 and 31 of the cylinder head.

Through these two flange portions are occupied coaxial holes 32 resp. 33 intended for a pin 34 insertable therein (see Fig. 1) through which the cylinder 5 is connected down and carried by the wedge 4. This is achieved by the guide or connecting pin 34 running in an elongate guide slot 35 in the wedge 4. This guide slot extends through the evenly thick main portion 36 of the wedge 4 below the edge guide flanges 14 of the wedge. In the right side of the wedge a threaded bottom hole 37 is accommodated in which the end of the piston rod 12 of the cylinder 3 is screwed. .

As can be seen from Figs. 4a and 4b, the cylinder head has in its four corner portions a first pair of axial holes 38 and a second pair of axial holes 39. These pairs of holes are intended for bolt connection of the cylinder head 23 with the cylinder housing 17 and 17, respectively. for axial control of the cylinder 5 relative to the mounting plate 2 at the bottom a pair of guide columns 40 inserted in the holes 39 and corresponding holes in the mounting plate (only one such column 40 is indicated in Fig. 1).

As can be seen from Fig. 1, both the wedge-pressing cylinder 3 and the presser foot-supporting cylinder S are provided with usual seals between the cylinder head and cylinder housing. Between the piston and the cylinder bore, the salt between the piston rod and its bore 10 15 20 25 30 35 _ 1- .y. ,., ,, a ,, a, ... yw-> 'fl ~' * 'V ~ 460 586 guide in the cylinder housing. The cylinders 3 and S are of course also provided with the required pressure medium channels for supply resp. removal of the pressure medium (in this case the compressed air) which affects and drives the respective piston.

On the lower part of the guide sleeve 211 projecting from the end wall 18 of the cylinder 5 is mounted axially adjustably a tool nose 41 working with lateral nail input, the lower part of which is constituted by the presser foot 6. By the tool nose with associated presser foot can be adjusted in different axial positions on the guide sleeve 21, the device can be adjusted to achieve the desired driving depth of the nail which is driven into the structural parts 7. by means of the piston rod 20 and a drive rod 42 coaxially inserted therein at the grooves 6 when the piston 19 performs its driving stroke. The length of this drive stroke is determined by the distance between the inside 43 of the cylinder head 23 and the inside 44 of the cylinder housing end wall 18.

For the sake of order, it may be pointed out that in tig. 1, the device is shown with the cylinder S and its tool nose 41 in a position not yet applied to the construction parts 7. 8. The positioning of the cylinder 5 and the tool nose against the structural parts is effected as described above by driving the cylinder 3 into the wedge 4 in the direction of the left nellan test plate 2 and the cylinder cover 23. When the pressure vessel 6 is brought into contact with the parts 7 and 9 and pressed together to close abutment against each other before the spin drive, the device is ready for activating the nail drive stroke of the cylinder 5. ie for driving the piston 19.

If we now imagine that the construction parts consist of a plasterboard 7 and a transverse wooden bar 8 located below it, it is necessary that the pressure force of the presser foot 6 does not become too great. i.e. the pressing force exerted by the presser foot against the gypsum board was locked to be limited to a value which does not give any residual indentation damage in the surface of the gypsum board.

An appropriate such maximum employment tax can be assumed to be S0 kp.

The actual nail driving, on the other hand, must take place with the help of a »~. v f w 'ff-a-ß- ny »- l4eo sauce 10 15 20 25 30 35 10 significantly greater force. for example 300 kp, which is exerted directly on the nail head below the drive rod 42. To provide an impact force of the magnitude S0 kp when the wedge angle u is about 14 'and when the force transmitting surfaces of the wedge 4. the mounting plate 2 and the piston tip 23 down the pin 34 are normal ground steel surfaces give a friction number in the range 0.01-0.08. so in the present case it is required that the cylinder 3 exerts a horizontal force of the size of about 32 kp on the wedge 4 in the direction to the left in Fig. 1.

The drive of the device then means that first the cylinder 3 presses the force about 32 kp into the wedge 4 between the mounting plate 2 and the piston top 23. and then the drive piston 19 is activated in the cylinder S 1 and to effect the nail drive stroke.

The cylinder 5 is therefore so dimensioned and compressed air of such pressure that the piston 19 provides a vertical driving force of the size 300 kp via the percussion rod 20 and the drive rod 42. When the nail driving has taken place, the device must be relieved to provide space for moving the parts. 7 and 8 and a possible renewed nail drive at a new location. During this force relief of the device, the piston 11 of the cylinder 3 first returns to its wedge-pulling end position. and then the piston 19 of the cylinder 5 returns to its upper. in Fig. 1 shows the gear position before a renewed nail drive.

As mentioned above, a coefficient of friction (friction number) for the wedge of the size 0.07-0.08 and a wedge angle of 14 ° are calculated. then a horizontal wedge traction force of the size ninst 33.0 kp a 24.8 kp is required to loosen the wedge. when densanna is still exposed to a vertical compressive force of 350 kp.

The wedge angle, son in this case selected to 14 °. hear for ground steel be at least l0 °. not larger than 20 ”.

It is important to choose the correct wedge angle in relation to the current coefficients of friction for the wedge plane and the compressive force on the wedge in order to obtain the desired size of the downward engagement flfl lift 50- 1 ° V * n3t3 * "'the examples have been selected. Finally, it should be pointed out that the above-described exemplary embodiments of the device according to the invention are only exemplary, which also applies to the reported angular and pressure values.The invention can of course be varied within the scope of the following claims without being limited thereto. of what son is stated in the above special description section.

Claims (10)

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Nf .-.> ..-........-- ww ... ._-. wr .._.-.._. v ____ í ___ -___ í ___ í__m_i_ fl _______________ _ _ o '. 4eo sšéf Patentkrav Device for nailing two structural parts (7, 8) together by pushing a nail through one structural part. for example a gypsum board (7), and further into the second construction part. for example, a rule (8). by means of a first linear motor in the form of an axially movable attachment to a frame part (1). first print media cylinder (5). for example compressed air cylinder. to which is attached a presser foot (6) by which application force can be provided against the structural parts, and which working stroke of the piston rod 10 (20) of the first cylinder produces the nail impression. k ä n n e - t e c k n a d av att en andra. with the stand part (1) firmly connected. linear motor in the form of a smaller print media cylinder (3). for example a second compressed air cylinder. is arranged for tight fitting of the first cylinder and its presser foot against the structural parts. to pour them together when pressing the nail. which second cylinder (3) is arranged so that its piston rod (12) is displaceable in a direction substantially perpendicular to the direction of movement of the piston rod (20) of the first cylinder. and that at the free end of the piston rod (12) of the second cylinder is attached a face facing the frame part (1) between the first cylinder. rear part (23) and the frame part retractable wedge (4) for effecting the engagement of the first cylinder with substantially constant engagement force and maintaining the presser foot bearing against the structural parts even in the case of local further compression of the parts during nail driving. Device according to Claim 1, characterized in that in the rear part (23) of the first cylinder (S) there is a leaky open guide latch (24) for the wedge (4). which splr has a flat bottom surface (25) whose normal direction forms an acute angle (a) with the direction of movement of the piston rod (20) of the first cylinder. which acute angle corresponds to the wedge angle of the wedge (u) - 10 15 20 25 30 35 ~ - 460 586 ' Device according to claim 2, characterized in that the wedge angle (α) has a value in the range 10'-20 °. and * preferably between 12 'and 16'. so that a wedge driving force Iz produced by the second cylinder (3) imparts to the first cylinder an actuating force II of the order of 1.5 to 1.6 times Iz. note the construction parts. at a wedge angle of say 14 'and a friction number between 0.07 and 0.08. ... bg Device according to claim 2 or 3, characterized in that the first cylinder (S) comprises a prismatic cylinder housing (17) with a cylindrical bore (22) for the movably movable therein. down piston rod (20) fitted piston (l9). to which the rear end of the cylinder housing is attached a cylinder cover (23) closing the rear end of the barrel in which the guide groove (24) for the wedge (4) is formed. Device according to claim 3 or 4, characterized in that the front part of the cylinder housing (17) has a guide sleeve (21) projecting from the present cylinder housing end wall (18) for the piston rod (20). characterized in that the second cylinder (3) is attached to a mounting plate (2) arranged on the frame part (1) on the side of which adjacent to the wedge a pair of parallel guide rulers (16) are mounted with which edge guide flanges (14) on the grooved sides of the wedge (4) are in sliding guide engagement. Device according to one of Claims 2 to 5. Device according to any one of claims 2-6. characterized in that the wedge (4) is interconnected with the first cylinder (S) at the bottom of a guide pin (34) arranged perpendicularly to the longitudinal direction of the guide groove (24). son is attached to the rear part (23) of the cylinder and extends across the guide groove at a distance from and parallel down the bottom surface (25) of the groove. and which guide pin extends through an elongate guide slot (35) in the shaft. which slot extends parallel down the side of the wedge to the groove bottom (27). _. amu fl ms-n-n. 10 15 20 g I 460 ssé '.l Å 14 Device according to Claim 5, characterized in that the presser foot (6) comprises a device which is axially adjustable on the guide sleeve (21). preferably down sideways nail loading working tool nose (41) son is employed note the construction parts at the nail drive. Device according to any one of the preceding claims. k a n n e - t e c k n a d in that in the first cylinder (5) there are axially spaced end position stop means (43. 44) for the percussion piston (19) movable in the cylinder. which means order the working stroke length of the piston and then the splitting length, as well as the size of the depression depth of the nail head in the upper structural part. Device according to any one of claims 4-9. k 3 n n e - t e c k n a d in that the end position stop means are constituted on one side by the inside (43) of the cylinder head. and. 8 the other side. the inside (44) of the cylinder housing wall wall passed through the piston rod (20) (18).