EP0292604A2 - Device for mechanically fastening roof sealing foils and insulating materials to roofs - Google Patents

Abstract

A method and corresponding apparatus accurately and efficiently fasten roofing materials to a roof. A first stroke of a piston both separates a single roofing screw from a roofing screw magazine and delivers it to a premounting position and separates a metal bracket from a metal bracket magazine and delivers it to a metal bracket premounting position. The second or return stroke places the screw and the metal bracket into respective mounting positions. A power screwdriver screws the screw through the metal bracket and the roofing materials placed on the roof and into the ceiling structure. The apparatus is mounted on a mobile frame to allow easy movement of the apparatus from fastening position to fastening position on the roof.

Description

The invention relates to a method and a device for carrying out the method for mechanically fastening roof sealing films and associated insulation materials on roofs.

Flat roofs of all kinds are covered with roof sealing foils and selected insulation materials.

Since the roofs are mostly large, manual laying techniques, which are subject to high labor intensity, have proven to be unprofitable but also dangerous.

Conventional laying techniques are also qualitatively unfavorable with regard to the sealing properties, since the mounting elements used are not correctly inserted into the existing ceiling constructions.

The invention is therefore based on the object of creating a rational, labor-friendly and labor-intensive and safe method for mechanically applying and fastening roof sealing films and associated insulating materials of all kinds on roof surfaces.

The invention is also based on the object of providing an apparatus for carrying out this method.

These objects are achieved according to the invention in that the method for mechanically fastening roof sealing foils and associated insulation materials on roofs, in particular on trapezoidal sheets or on gas concrete and on flat roofs of all kinds, is characterized in that the film and the insulation materials are loosely mechanically by means of loosely arranged metal holders and roof screws , mechanically fixed, are connected to the subsurface, the metal brackets and roof screws each passing through a single one, the work cycles of which are coordinated so that first a metal bracket and a roof screw are presented, then the metal bracket and then the roof screw are guided into the final assembly position, while the supply of further metal brackets and roof screws is blocked, from where they are inserted into the roof surface by means of a vertically positioned screwdriver and after the completion of each assembly process, a further combination consisting of a us a metal holder and a roof screw, pre-stored for assembly.

A special embodiment of the device for carrying out the method for mechanically fastening roof sealing films and associated insulation materials on roofs, in particular on trapezoidal sheets or gas concrete and on flat roofs of all types, is characterized in that the device preferably has a mobile frame on or in which the magazines are arranged for storing the loose metal brackets and roof screws with their singles as well as feed and working elements,
that the separator of the metal holder has a rotatably mounted locking disk that sits diagonally on the base plate with an internal recess in size and shape of the metal holder, the geometric material thickness of the locking disk corresponding to that of the metal holder,
that the individual of the roof screws consists of a cam-controlled, preferably cylindrical, rotatably mounted roller provided with locking levers,
that the magazine of the metal holder preferably consists of corner holders arranged perpendicular to the base plate by means of screws at an angle to the base plate axis,
that the magazine of the roof screws consists of screw tracks that are parallel to one another and inclined relative to the device axis, which lead into a screw track that runs at a downward gradient and leads to the cam-controlled locking lever roller.

Another particularly preferred embodiment of the device is characterized in that
that the supply of the metal holder is carried out in the assembly position via a lever-controlled slide, the levers controlling the slide on both sides being activated by vertical pressure force, while the levers are guided in two vertically and horizontally arranged grooves, and the slide is milled out within a longitudinally movable Move the rail, which thus rotates it with a time-delaying nose,
that the roof construction screws are fed in via the lever of the cam-controlled roller which engages in the feeder device, in that the latter is pivoted into a release position by a lock,
that the locking lever roller has a vertically running curved groove into which a nose arranged on the piston vertically movable in the pressure column engages, that the locking lever roller has a nose which engages in a curved groove arranged vertically movable in the pressure column,
that a guide sleeve centering the screwdriver is arranged vertically above the assembly end position of the metal holder and has a recess in the wall that allows the roof screw to enter the assembly end position,
that the pressure column provided with an internal spring is telescopically retractable into the housing, two handles extending transversely to the column axis and a retaining claw provided for fastening the screwdriver being arranged on the pressure column.

Another particularly preferred embodiment is characterized in that a spring block is arranged within the pressure column, which is connected by means of a dynamic spacer to the piston which can be moved vertically in the pressure column, the elongated hole provided in the spacer causing a time delay in the piston movement.

Another particularly preferred embodiment is characterized in that the telescopic part retractable within the pressure column has a slot-shaped recess on both sides.

• Figur 1 einen Querschnitt der erfindungsgemäßen Vor­richtung;
• Figur 2 eine Draufsicht der erfindungsgemäßen Vor­richtung;
• Figur 3 bis 5 ein Detail der kurvengesteuerten Sperrhebel­walze mit Schraubenzuführung und Vereinzelner;
• Figur 6 und 7 ein Detail des Metallhaltervereinzelners mit Zuführung;
• Figur 8 und 9 Systemzeichnungen, die die Arbeitstakte des Verfahrens erläutern;
• Figur 10 einen Querschnitt der Schiebersteuerung;
• Figur 11 eine Draufsicht der Figur 10
• Figur 12 bis 14 die Drucksäule in verschiedenen Arbeits­positionen.

With reference to the accompanying drawings, which show a particularly preferred embodiment of the invention, this will now be explained in more detail.
Show:

• Figure 1 shows a cross section of the device according to the invention;
• Figure 2 is a plan view of the device according to the invention;
• Figure 3 to 5 shows a detail of the cam-controlled locking lever roller with screw feed and singler;
• Figures 6 and 7 show a detail of the metal holder separator with feed;
• FIGS. 8 and 9 are system drawings which explain the work cycles of the method;
• Figure 10 shows a cross section of the slide control;
• FIG. 11 is a top view of FIG. 10
• Figure 12 to 14, the pressure column in different working positions.

Figures 1 and 2 show a cross section and a plan view of the device according to the invention.

The frame 1 of the device is preferably designed to be movable by a pair of wheels or rollers 2. Here, only one pair of wheels 2 in the area of the pressure column 3 has proven to be expedient, since the device is moved on these rollers by a slight tilting position and rests on the foot support 4 during assembly use. If necessary, the bottom surface of the foot piece 4 can be covered with a non-slip covering, for example with a rubber pad.

The device is operated as follows:
The roof screws 6 are filled into the screw magazine 5.
The metal holders 7 are also inserted into the magazine 8 provided for them.

Since the individual tracks 9 of the screw magazine 5 lead into a single track 10 arranged with a slope, a screw 6 is already in front of the locking lever roller 11.
At the start of installation, a "filling operation" is required, ie the operator presses the pressure column 3 to "A".

As a result, the piston 12 is also moved to "A". About the lever 13, the slider 14 is moved to "B" (dash-dotted position) and rotates by means of a driver the individual before 15 still oblique to the device axis of the metal holder 7 to "C", so that the recess 18 of the separator 15 with the Recess 17 of the base plate 16 is congruent.

The metal holder 7, the material thickness of which corresponds to that of the separator 15, now falls through both recesses 17 and 18 in the base plate 16 and the separator 15, which recesses are formed in accordance with their geometric shape.

A special feature of the invention is that only a metal holder is presented - therefore singular - this will be discussed in more detail in Figures 6 and 7.

After pressing the pressure column 3 to "A", the metal holder 7 lies in front of the slide 14 which is pulled backwards. The locking lever roller 11 was also pivoted to "D" when the lower point of the pressure column 3 was reached, so that a screw 6 was placed in front.

If the force applied to "A" ceases, the pressure column 3 is moved to "B" by a spring. Here, the slide 14 is again moved into its starting position via the lever 13 and thereby guides the metal holder 7 in the assembly position. The work cycles are coordinated with one another with a time delay so that the locking lever roller 11 pivots to "E" only after the metal holder 7 has reached the assembly end position and presses the screw 6 into the guide sleeve 19 of the screwdriver 20.

The pressure column 3 has reached its uppermost point at this time.

The work cycles that follow are analogous to those described above, but when pressing the pressure column 3 to "A", a combination of holder 7 and roof screw 6 is installed, i.e. the screwdriver 20 screwed the parts into the ceiling structure during this work cycle.

FIGS. 3 to 5 show a detail of the cam-controlled locking lever roller 11.

The screws 6 are on the screw track 10 on the Template 21 on. The nose 22 guided in the pressure column 3 passes during the vertical movement to "A", the curve 23 present in the locking lever roller 11, the locking lever roller 11 rotating by "P" to "D" and the locking lever 24 out of the recesses 25 of the locking lever roller 11 pivot and release the path of the screws 6 in the notch 26.

If the stroke is carried out to "B", the locking levers pivot to "E" and put the screws 6 through the opening 27 of the guide sleeve 19 into the final assembly position, where it is located above the metal holder that has already been inserted, and is inserted into the ceiling structure using a screwdriver.

Figures 6 and 7 show a detail of the metal holder separator.

The metal holders 7 are stacked one above the other in the magazine 8, the axis Z of which is arranged obliquely to the device axis X. This has the consequence that the metal holder can not fall through the recess 17 of the base plate 16, which has the shape of the metal holder.

The separator 15, which is rotatably mounted about the center "Y" of the base plate 16, lies in a recess 28 in the base slot 16. The geometrical material thickness of the recess 28, the separator 15 and the metal holder 7 are congruent, so that a metal holder has the same area in the recess 18 of the recess Separate concerns. If the separator is rotated to "C" as described at the beginning, the recess 17 of the base plate 16, the recess 18 of the separator 15 and a metal holder 7 are placed congruently one above the other, while all other metal holders in the magazine are held obliquely in the Z axis, so that only a metal holder falls through all the recesses in front of the slide 14.
At the corresponding work cycle, the metal holder is pushed to the "Mo" end position after "F".

Figure 8 shows the operations when the pressure column moves downward.

Point A is the starting position at which the pressure column is in its upper point when not actuated.

Slider, (S), metal holder single (M) and locking lever roller (W) are in rest position I.

When the pressure column reaches position "B", the slide is moved.
Metal holder singler (M) and locking lever roller (W) remain in their positions.

When the pressure column reaches position C, the singler swivels in the "X" axis. A metal holder falls in front of the slider. The slide and locking lever roller remain in their current position. When the pressure column reaches point D, the locking lever roller swivels to "i" and releases the screw from "K" to "L".
The time delay which causes the slide function is explained in more detail in FIGS. 10 and 11.

Figure 9 shows the working movement of the pressure column upwards. After reaching point "E", the slide moves back and places a metal holder in the assembly end position. Separator (M) and locking lever roller (W) hold their position.
Point F moves the locking lever roller to "h" and sets the screws in the final assembly position "M".
Point G corresponds to the starting point A and rotates the singler in its axis "Z".

After the pressure column has descended again, the work cycles described are repeated, the screwdriver introducing the parts in the final assembly position into the ceiling structure.

Figures 10 and 11 illustrate the procedure of the time delay due to the slide movement. The slide 14 is moved via the lever 13 to "x". The slider 14 guides a rail 30 within a recess 29.

As soon as the slide 14 strikes the inside 31 of the rail 30, it moves it to "y". The nose 32 arranged on the rail engages in a recess 33 of the separator provided specifically for this purpose and rotates it in the form already described. The time delay is caused by the free movement of the slide 14 between the inner sides 31 (31 a) of the rail 30.

Figures 12 to 14 show the pressure column 3 in different working positions. A spring block 34, against which the spring 35 presses, is arranged within the pressure column 3. A dynamic spacer 36 connects that within the pressure column telescopic part 37 with the pistons 12. If the telescopic part 37 provided with recesses 39 is retracted to "A", the piston is moved vertically downward with a time delay. The time delay is caused by the elongated hole 38 arranged in the spacer.

This method and the proposed device represents a method of operation which processes the sealing film efficiently.

Reference symbol list

• 1 frame
• 2 pairs of wheels
• 3 pressure column
• 4 foot sockets
• 5 screw magazine
• 6 roof screws
• 7 metal holders
• 8 metal holder magazine
• 9 single tracks of the screw magazine
• 10 single track with gradient
• 11 locking lever roller
• 12 pistons
• 13 levers
• 14 sliders
• 15 singles
• 16 base plate
• 17 Cut-out in the base plate
• 18 Cut-out of the separator
• 19 guide sleeve
• 20 screwdrivers
• 21 template
• 22 Nose on the piston
• 23 curve
• 24 locking lever
• 25 notches in the locking lever roller
• 26 notch
• 27 opening
• 28 screwing
• 29 recess
• 30 rail
• 31 Inside of the rail
• 32 nose on the rail
• 33 Cut-out in the individual
• 34 spring blockage
• 35 spring
• 36 dynamic spacers
• 37 telescopic part
• 38 slot
• 39 Recess in the telescopic part

Claims (14)

1. Process for the mechanical fastening of roof sealing foils and associated insulation materials on roofs, in particular on trapezoidal sheets or on gas concrete and on all types of flat roofs,
characterized,
that the film and the insulation materials are connected mechanically and mechanically to the substrate by means of loosely arranged metal brackets and roof screws, whereby the metal brackets and roof screws each pass through a single element, the work cycles of which are coordinated so that a metal bracket and a roof screw are initially presented , then the metal bracket and then the roof screw in the final assembly position, while the supply of further metal brackets and roof screws is blocked, from where they are inserted into the roof area using a vertically positioned screwdriver and after the completion of each assembly process, another combination consisting of a Metal bracket and a roof screw, pre-stored for assembly. 2. Device for carrying out the method according to claim 1,
characterized by
that the device preferably has a mobile frame, on or in which the magazines for storing the loose metal holders and roof screws with their singles and feed and working elements are arranged. 3. Device according to claim 1-2,
characterized,
that the separator of the metal holder has a rotatably mounted locking disk, which sits diagonally on the base plate and has an internal recess in the size and shape of the metal holder, the geometric material thickness of the locking disk corresponding to that of the metal holder. 4. Apparatus according to claim 1-3,
characterized,
that the individual of the roof screws consists of a cam-controlled, preferably cylindrical, rotatably mounted roller provided with locking levers. 5. The device according to claim 1-4,
characterized,
that the magazine of the metal holder preferably consists of corner holders arranged perpendicular to the base plate by means of screws at an angle to the base plate axis. 6. The device according to claim 1-5,
characterized,
that the magazine of the roof screws consists of screw tracks that are parallel to one another and inclined relative to the device axis, which lead into a screw track that runs at a downward gradient and leads to the cam-controlled locking lever roller. 7. The device according to claim 1-6,
characterized,
that the supply of the metal holder is carried out in the assembly position via a lever-controlled slide, the levers controlling the slide on both sides being activated by a vertically running pressure force, while the levers are guided in two vertically and horizontally arranged grooves, and the slide is milled out within a longitudinally movable Move the rail, which thus rotates it with a time delay via a nose engaging in the singler. 8. The device according to claim 1-7,
characterized,
that the supply of the roof screws takes place via the lever of the cam-controlled roller which engages in the device of the supply, in that the latter is pivoted into a release position by a lock. 9. The device according to claim 1-8,
characterized,
that the locking lever roller has a vertically running curved groove into which a nose arranged on the piston which is vertically displaceable in the pressure column engages. 10. The device according to claim 1-8,
characterized,
that the locking lever roller has a nose which engages in a curved groove arranged vertically movable in the pressure column. 11. The device according to claim 1-10,
characterized,
that a guide sleeve centering the screwdriver is arranged vertically above the assembly end position of the metal holder, which is the roof screw in the assembly Recessing recess of the wall. 12. The apparatus of claim 1-11,
characterized,
that the pressure column provided with an internal spring is telescopically retractable into the housing, two handles extending transversely to the column axis and a retaining claw provided for fastening the screwdriver being arranged on the pressure column. 13. The apparatus of claim 1-12,
characterized,
that a spring block is arranged within the pressure column, which is connected by means of a dynamic spacer to the piston which can be moved vertically in the pressure column, the elongated hole provided in the spacer causing a time delay in the piston movement. 14. The apparatus of claims 1-13,
characterized,
that the telescopic part retractable within the pressure column has a slot-shaped recess on both sides.

Images