NL1011710C1 - Drive for plastic covering film. - Google Patents

Description

DRIVE FOR PLASTIC COVER FILM

The invention relates to a building construction consisting of a framework of posts and beams of profile material, which is covered on the outside with sheet-like material such as plastic foil, wherein the foil is attached with a longitudinal beam connected to the frame on at least the roof part with a longitudinal edge. wherein a second longitudinal beam is attached to the parallel opposite longitudinal edge of the film and is rotatably rotated about its axis, such that the second beam wraps in and out of the film, respectively, and the drive is formed by a reversible motor.

Such a construction has previously been described in an earlier patent by applicant, which embodiment 15 assumed that the drive motor of the roller system stalls at a fixed number of revolutions. Since the deck consists of a foil, usually plastic film, this deck is temperature sensitive. It is therefore possible that the film does not have the correct tension when the prescribed number of revolutions is reached. If too few revolutions have been made, the foil is too weak; too many revolutions tears the foil or burns the motor.

Therefore, in such a construction, the motor must be very accurately adjusted and regularly adjusted. Due to the hot or cold weather, the film will stretch or shrink, so that the film will never have the optimum tension with the film once unrolled.

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The object of the invention is to improve the drive of the building system as described in the preamble, and to that end it proposes to provide the drive with a resistance-sensitive sensor element, which controls the power supply of the motor to switch it off.

If an electric motor is used, it is preferable to include an electrical resistance in the power supply, which senses when the current or voltage in the power system 10 increases, respectively, and the control signal of which can enclose the power supply.

According to a further embodiment, the electric motor can drive the second longitudinal beam via a self-braking transmission system. If the power supply of the electric motor fails, the system will then remain self-braked.

The resistance measurement with electro-drive can also take place thermally or in any other suitable manner, for example electronically.

According to another embodiment of the invention, the motor supply can also be limited by a mechanical torque limiter.

The invention is further elucidated in the figure description below of an exemplary embodiment. In the drawing: figure 1 shows a perspective top view of a building construction according to the invention; figure 2 shows a perspective view according to arrow II of a detail of the ridge construction of a part of the frame of figure 1; Figure 3 shows a perspective view according to arrow III in figure 1, of a part of the drive of the second longitudinal beam with foil wound thereon; figure 4 shows a perspective view according to arrow IV, in which the winding and tensioning function of the second beam is explained in more detail.

The building construction shown in figure 1 consists of a framework or assembly of uprights 1, longitudinal and cross members 2 and 3, respectively, as well as curved cross members 17 1710 3, on which a longitudinal member 5 is fixed at the highest point thereof. All these parts are formed from profile material or composite profile material.

If desired, cross-ties can be applied, which can be formed by rods 6 on the left in figure 1 or tension wires 7 between the curved sleepers 4.

As shown, the exterior of the framework is covered with plastic film, which is indicated by 10 along the side panels of the framework and 11 on the roof portion.

With reference to Figures 1 to 4, the fastening and rolling method of the cover foil 11 for the roof section is explained in more detail.

The foil 11 is fixed with a longitudinal edge 12 to the roof longitudinal beam 5, see figure 2, which beam here consists of two spaced apart profiles 13, the bottom flange of which is fixed on the curved cross beam 4. The longitudinal edge 12 is clamped by means of a clamping strip 14 against the long leg of the profile 13.

The foil material 11 has a length corresponding to part or all of the length of the building structure to be spanned, and a width corresponding at least to half of the curved crossbeam of the framework.

The free edge strip of the film 11, which is parallel to the edge strip 12 and which is located in the covering condition near the lower end of the curved cross-members 4, is attached to a second longitudinal beam in the form of a rod or pipe 15, see also Figure 3, which is rotatably driven about its axis, which is further elucidated below, such that the rod can wind in and out of the foil 11, respectively. It is thus possible to roll up half of the span of the transverse truss 4 from the bottom to the first longitudinal beam 5 and unroll it in the reverse direction to cover the frame.

101 1 7; 0 4

For the drive, reference is made to Figure 3, in which it can be seen that the foil web 11 is locally interrupted, wherein two closely adjacent transverse frames 4 are arranged. In the distance 5 between the transverse trusses 4, the free second longitudinal beam 15 is formed with a sprocket 20, around which a chain 21 is wrapped. This leads to a second sprocket 22 on the output motor shaft 23 of an electric motor 24. This electric motor 24 is mounted in a subframe 10, in the form of a U-shaped bracket, to which a reaction rod 26 is attached. The reaction rod is connected via a sliding connection 27 to a longitudinal beam 2 of the frame. All this is designed in such a way that the reaction rod 26 can slide transversely to the longitudinal beam 2 if the subframe 25 moves along the underside of the curved transverse frame 4.

This movement is effected by an appropriate actuation of the motor 24 in some sense of rotation, so that in the chain transmission 21 the wheel 20 is brought into rotation and thus the bar 15. Depending on the direction of rotation, the bar will therefore move in and out of the foil web 11, respectively, in the direction of the arrow PI, see figure 3.

The chosen construction makes it possible for the motor with drive to be located under the foil web 11, whereby the construction is protected against weather influences.

It is noted that the gap between the two adjacent transverse rafters 4 can be covered with a cover (not shown).

Within the scope of the invention other drives are possible, for instance a central motor which is connected via a cable, chain system or the like to the second longitudinal beam 15 in order to drive them in one or the other rotary sense.

In order to pull the foil tightly over the curved cross-members or rafters 4., it is preferable to design the lower edge construction of the covering close to 1 fj <<7 i -5 5 * the intermediate gutter profiles 30 such that the lower edge overhangs the gutter profile 30, see figure 4. This overhang is achieved here by providing the gutter profile 30 upwards with a bracket 5 31 on the free edge 32 of which a tube 33 is attached. The lower ends of the rafters 4 end on this tube 33.

When the second longitudinal beam 15 is unrolled from the film 11 in the direction of the arrow P2, with a sufficient width of the film 11, the pipe 15 will drop down past the pipe 33 to the position indicated by A in figure 4. By rotating the longitudinal beam 15 in the same direction P2, the tube will wrap on the other side of the foil and finally clamp itself under the longitudinal tube 33 to indicate the position with B in figure 4. In this way the film web 11 is pulled tightly over the fixed longitudinal tube 33 and under normal circumstances the film rests firmly on the sleepers 4 without any play.

Under different circumstances, for example a higher temperature, the foil will be able to have more play, which is prevented by providing the electric motor 24 with the resistance sensor proposed according to the invention, as discussed above. The motor 24 is turned in the direction of the arrow P2 25 until the foil is pulled tightly over the rafter 4, after which the driving resistance increases such that either the temperature of the motor increases, or the voltage or current increases at the power supply, which can are sensed by appropriate sensors that give a signal for engine shutdown.

The motor can be equipped with a self-braking transmission, so that the correct tension remains in the foil, or other locking systems are used.

The film is loosened and wound up 35 by driving the longitudinal beam 15 in the reverse direction, so that position A is first reached and then winding up begins before opening the roof part of the building construction.

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The motor 24 is of arbitrary nature within the scope of the invention and may also be a hydraulic motor.

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Claims (4)

Building construction consisting of a framework of posts and beams of profile material, which is covered on the outside with sheet-like material such as plastic foil, wherein the foil is fixed with a longitudinal edge on at least the roof section with a longitudinal beam connected to the framework, whereby a second longitudinal beam is attached to the parallel opposite longitudinal edge of the film and is rotatably rotated about its axis, such that the second beam winds in and out of the film, respectively, and the drive is formed by a reversible motor, with the characterized in that the drive is provided with a resistance-sensitive sensor element, which controls the power supply of the motor to switch it off. Building construction according to claim 1, characterized in that the motor is provided with a transmission which is self-braking. Building construction according to claims 1 and 2, characterized in that a resistance sensor or temperature sensor is included in the supply circuit of the drive designed as an electric motor. Building construction according to claim 1, characterized in that the drive comprises a mechanical torque limiter. 25 101 1710