GLAZING PANEL REMOVAL

Abstract

A glazing panel removal device comprising a winder unit (1) having first and second winder spools (10, 11) for winding a cutting filament (100) and a drive, for driving the winder spools (10). The drive means includes a single or common drive input for driving both the first and second winder spools (10, 11). The drive maybe a rotary input drive, and driving the rotary input in a first rotary direction may cause winding of the filament (100) onto the first winder spool (10) and driving the rotary input in the opposite direction causes winding of the filament (100) onto the second winder spool (11).

Claims

1. A glazing panel removal device comprising a winder unit having: first and second winder spools for winding a cutting filament; and drive means for driving the winder spools, wherein the drive means comprises a single or common drive input for driving both the first and second winder spools.

2. The glazing panel removal device according to claim 1, wherein: the drive means comprises a rotary input, and driving the rotary input in a first rotary direction causes winding of the filament onto the first winder spool and driving the rotary input in the opposite direction causes winding of the filament onto the second winder spool.

3. The glazing panel removal device according to claim 1, wherein: the drive means is arranged to be configured to drive one of the first and second winder spools, whilst permitting the other of the first and second winder spools to rotate without being driven.

4. The glazing panel removal device according to claim 3, wherein: the drive means is arranged to be configured to drive the first and second winder spools such that the filament is wound onto one of the first and second winder spool whilst being wound simultaneously off the other of the first and second winder spool.

5. The glazing panel according to claim 1, wherein: the drive means is arranged to be configured such that the filament is prevented from winding off one of the first and second winder spools whilst being wound on to the other of the first and second winder spools.

6. The glazing panel removal device according to claim 1, wherein: the device includes an adjustable brake arrangement arranged to vary the torque required to wind the filament off either of the first and second winder spools.

7. The glazing panel removal device according to claim 1, wherein: the drive means comprises an input drive shaft comprising the drive input and separate transmission shafts transmitting rotary motion to drive respective winder spools, the transmission shafts extending transversely to the input drive shaft.

8. The glazing panel removal device according to claim 1, wherein: the device includes a transmission comprising a common bevel gear arrangement for transmitting rotary motion to each of the first and second winder spools.

9. The glazing panel removal device according to claim 1, wherein: the device includes a transmission comprising respective one way bearings for transmitting rotary motion to each of the first and second winder spools.

10. The glazing panel removal device according to claim 1, wherein: one or both of the first and second rotary winder spools are demountable from the unit.

11. The glazing panel removal device according to claim 1, wherein: one or both of the first and second winder spools are arranged to be mounted with respect to a driven shaft in an engaged position in which the winder spool is coupled to rotate with the driven shaft and a neutral position in which the winder spool can rotate independently of the driven shaft.

12. The glazing panel removal device according to claim 1, wherein: the first and second winder spools are mounted to rotate on axes that are substantially co-axial with one another.

13. The glazing panel removal device according to claim 1, wherein: the device further comprises mounting means for mounting the device to a glazing panel.

14. The glazing panel removal device according to claim 13, wherein: the mounting means comprises one or more suction mounts.

15. A glazing panel removal device comprising: mounting means for mounting the glazing panel removal device on the glazing panel; and first and second winder spools for winding a cutting filament, wherein the rotational axes of the first and second winder spools are orientated substantially i) coaxial with one another, and/or ii) with axes horizontal or parallel with respect to the general plane of the vehicle glazing panel.

16. A glazing panel removal device comprising a winder unit having: first and second winder spools for winding a cutting filament; and a drive transmission for driving the winder spools, wherein the drive transmission is arranged to drive one of the first and second winder spools, whilst permitting the other of the first and second winder spools to rotate without being driven.

17. The glazing panel removal device according to claim 16, wherein: the drive transmission is arranged to be switched to permit the other of the first and second winder spools to be driven whilst the remaining winder spool rotates without being driven.

18. A glazing panel removal device comprising: a winder unit having at least one winder spool for winding a cutting filament, wherein the winder spool is arranged to be mounted with respect to a driven shaft in an engaged position in which the winder spool is coupled to rotate with the driven shaft and a neutral position in which the winder spool can rotate independently of the driven shaft.

19. A glazing panel removal device comprising: a winder unit having at least one winder spool for winding a cutting filament, wherein the winder spool is arranged to be mounted or coupled with respect to a driven shaft by magnetic means.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0041] FIG. 1 is a plan view of an exemplary embodiment of winder unit in accordance with the invention;

[0042] FIG. 2 is a sectional view of the winder unit of FIG. 1;

[0043] FIG. 3 is a schematic view of an exemplary winder unit according to the invention;

[0044] FIGS. 4A to 4E are schematic representations showing operation of the transmission/drive train of a unit in accordance with the invention;

[0045] FIGS. 5A and 5B show schematically the configuration if an adjustable friction brake arrangement suitable for operating in accordance with the invention;

[0046] FIGS. 6A and 6B show how the winder spools are mounted to the transmission shaft in accordance with an aspect of the invention;

[0047] FIG. 7 is a perspective view of the embodiment of FIGS. 1 and 2.

DETAILED DESCRIPTION

[0048] Referring initially to FIGS. 1 2 and 7 in particular, there is shown a glazing panel removal device 1 in the form of a winder unit 1 to be mounted on a vehicle glazing panel, and in a first mode of operation being capable of being used with a cut out wire in a similar manner to the unit disclosed in WO2006/030212. In an alternative mode of operation the unit can be used in combination with a plastics fibre line filament in place of a cutting wire.

[0049] The unit is similar in certain respects to the winder unit disclosed in WO2006/030212, particularly in that it utilises a pair of spaced suction mounts 52 and also a pair of spaced winder spools 10,11 for winding the cutting filament in the worm either of the cutting wire or the cutting plastics fibre line. The unit also includes rotatable guide pulleys 54 55 56 57 for guiding the cutting filament 100 which are arranged in similar configuration to the arrangement of FIG. 12 in WO2006/030212.

[0050] The unit includes further 2 inclined or angled pulleys 61 62 which are provided to guide the filament 100 as it is wound onto and off a respective winder spool 10 11. These pulleys are provided because, contrary to the arrangement of WO2006/030212, the winder spools 10,11 are arranged upright, coaxially with one another and with their rotational axis horizontal (i.e. parallel to the general plane of the glazing panel to which the unit is mounted). This for ergonomic and ease of use reasons, particularly because the winder spools are demountable from their respective drive shafts 16 17 and the arrangement in this configuration makes for easy mounting and de-mounting.

[0051] A further departure from the arrangement shown in WO2006/030212 is that a single drive for driving both the winder spools 10 11 is provided. The single drive comprises a socket 64 coupled to a drive shaft 14. In one embodiment a rotary manual handle 68 can be coupled to drive the drive shaft 14 via the socket 64. In an alternative embodiment a powered drive tool can be coupled to the drive socket 64. The transmission system for driving the spools 10 11 will be described in detail below.

[0052] As shown in FIG. 2 the transmission for rotating the winder spools 10, 11 comprises a vertically orientated input drive shaft 14 to which is mounted a mitre gear 15. The mitre gear 15 drives a respective drive gear 22 23 for a respective spool drive shaft 16 17 to which the spools are mounted. Shaft bearings 18 are provided for the input shaft 14 and the drive shafts 16 17.

[0053] Importantly the gears 22 23 act to drive the shafts 16 17 through respective one way bearings 12 13. These ensure that torque is only transmitted to the respective drive shafts 16 17 when the respective gear 22 23 is rotated in one direction (opposite rotation directions for each of the gears 22 23). One way bearings are known in the art.

[0054] Also mounted to the respective shafts 16 17 are respective adjustable friction brake arrangements 41 42 which are controlled by operating a rotary control annulus 41a 42a which is cam profiled to urge a movable brake disc 25 26 to frictionally engage with fixed washers 27 in order to provide a braking effect. An alternative exemplary arrangement is shown in the schematic embodiment of FIGS. 5A and 5B in which a wave compression spring 26 is provided between the brake actuator 42b and a friction washer 81. The friction washer 81 acts against a friction plate 82 mounted by means of a one way bearing 30 to the shaft 17. The control annulus 42a and the brake actuator 42b are cam profiled such that rotation of the annulus 42a results in axial movement of the brake actuator 42b.

[0055] In the embodiment of FIGS. 1, 2 and 7 a series of fixed and rotary brake discs indicated at 27. The brake arrangement does not rotate with the shaft 16 or 17. One way bearings 30 ensure that friction is not applied by the brake to the shaft 16 17 whilst winding in the filament on the respective spool 10, 11. The brake only takes effect for winding in the opposite direction.

[0056] In use the transmission can be used in 2 modes, these being slip mode (in which the filament 100 is simultaneously wound off one spool as it is wound onto another) and non-slip mode (in which the filament is wound onto one of the spools whilst not being wound off the other). In slip mode the tension can be adjusted using the brake devices.

[0057] Non-slip mode is shown in FIGS. 4A and 4B where the arrows show the rotation according to the right hand rule FIG. 4E. In FIG. 4A rotation of the drive shaft 14 and mitre gear 15 is clockwise. Torque is transferred via the one way bearing 13 to rotate the shaft 17 and spool 11 to wind in the filament 33. The one way bearing 30 on the brake device 41 is configured such that when the shaft 17 is driven, no brake is applied by brake 41.

[0058] In the situation of FIG. 4A the brake 42 is fully applied and effective by means of torque being applied via the one way bearing 30 of brake 42 so as to apply braking friction to the shaft 16 to a degree sufficient to prevent rotation. Torque is not applied through the one way bearing 12 of gear 22 to drive the shaft 16. Consequently filament is not wound off spool 10 because the tension in the filament 100 is not sufficient to overcome the braking force of the brake 42.

[0059] For counter clockwise winding of the drive shaft 14, the situation is reversed as shown in FIG. 4B and filament is wound onto spool 10 but not off spool 11. In this configuration torque is not transferred through bearing 30 of brake 42. Torque is however applied via the bearing 30 of brake 41. The transmission is driving the shaft 16 because torque is applied via the bearing 12. No torque is applied via the bearing 13.

[0060] This non-slip cutting is achieved when the brakes 41 42 are full applied (or at least sufficiently applied to prevent rotation as a result of tension in the filament).

[0061] If the brakes 41 42 are not fully applied, then the slip cutting situation shown in FIGS. 4C and 4D results. The braking force applied by the brakes 41 42 (when acting via the respective one way bearings 30) is not sufficient to prevent the tension in the filament on the winding off spool causing rotation of the spool 10 11 and slip cutting occurs as filament is wound off one spool whilst being simultaneously wound onto the other. In the clockwise drive shaft 14 rotation situation shown in FIG. 4C the shaft 17 is driven via the one way bearing 13 and the brake 41 torque is not being applied via the one way bearing 30. The one way bearing 30 of brake 42 is acting to transmit braking torque, but not sufficient to prevent the filament 100 from being wound off the spool 10. One way bearing 12 of gear 22 is not acting.

[0062] In the situation of counter clockwise rotation (as shown in FIG. 4D, the operation is reversed. Shaft 16 is driven by the active bearing 12 in order to wind on to spool 10. Shaft 17 rotates due to the torque applied via the filament 100 being wound off spool 11. Brake 41 is active but not sufficient to prevent the filament being wound off spool 11. Because the brake torque is adjustable, the tension in the filament required to effect winding off the relevant spool can be adjusted. This provides for adjustable slip cutting.

[0063] As an alternative to the transmission described, the gear train could be used to drive the shafts simultaneously in opposed directions but this would result in potentially a less versatile means of operation as the alternative modes of cutting would be more difficult to achieve.

[0064] The spools 10, 11 are mounted on respective drive shafts in 16 17 in two positions, a driving or engaged position in which they rotate with the driven shaft 16 17 and a neutral position in which they can rotate independently of the main drive shaft 16 17. The spools 10 11 are displaced axially outwardly from the drive position to the neutral position. In the neutral position the spools 10 11 are held to rotate with a rotatable shaft tip 16a 17a which is rotatably fixed to the main shaft 16 17 by a respective axis pin 71. This is shown most clearly and schematically in FIGS. 6A and 6B. FIG. 6A shows the spool 11 in the engaged position. FIG. 6B shows the spool 11 in the neutral position. The shaft tip 71 and the shaft are provided with magnets 92 93 and the spool has a ferrite insert 11a to ensure that the spool is held in the desired engaged or neutral position. A spring 73 is provided to control friction in the rotating tip 16a 17a.

[0065] The ability to engage neutral position is important to enable filament to be pulled off from the spools once it has already been wound on. This is necessary for example when using the fibre line filament during the set up procedure.

[0066] The cut out unit can be used in various techniques and procedures and is particularly versatile in this regard being capable for powered or manual use and also for use with traditional wire or the newer fibre line filament.

[0067] It should be noted that the above-mentioned embodiments illustrate rather than limit the invention, and that those skilled in the art will be capable of designing many alternative embodiments without departing from the scope of the invention as defined by the appended claims. In the claims, any reference signs placed in parentheses shall not be construed as limiting the claims. The word “comprising” and “comprises”, and the like, does not exclude the presence of elements or steps other than those listed in any claim or the specification as a whole. In the present specification, “comprises” means “includes or consists of” and “comprising” means “including or consisting of”. The singular reference of an element does not exclude the plural reference of such elements and vice-versa. The mere fact that certain measures are recited in mutually different dependent claims does not indicate that a combination of these measures cannot be used to advantage.