Flaws or voids such as cracks in bodies such as glazing panels occur in a variety of configurations. For example damaged vehicle windscreens may exhibit elongate running cracks, or breaks classified in the art as, for example, <BR> bulls-eye'starbreak', clover leafZ, bees wingt, half moon'or combination'. Frequently such damage flaws are repaired by means of introducing a repair material into the flaw or void, and subsequently hardening the repair material. For example, for repairing crack damaged glazing panels (such as vehicle windscreens) a flowable resin is introduced into the crack and subsequently permitted to harden. Repair resin may be applied under vacuum (to enhance de-gassing of the resin), and mechanical means (such as a plunger) may be utilised to force the resin into the crack. An arrangement has been proposed in which high frequency vibrations are imparted to the body to promote resin infilling breaks.

Such an arrangement is disclosed in US-A-3562366.

An improved repair technique has now been devised.

According to a first aspect, the invention provides a method of repairing a flaw or void in a body, the method comprising infilling the flaw or void with a repair material, wherein high frequency vibration means is applied to act on the body, the high frequency vibration means including a vibration delivery probe of a rigid material.

According to a second aspect, the invention provides apparatus for use in repairing a flaw or void in a body, the apparatus comprising high frequency vibration means including a vibration delivery probe of a rigid material, the probe being positionable to act on the body.

The use of a rigid material for the delivery probe (preferably a hard metallic material such as titanium) enables ultrasonic vibration of sufficient amplitude to be achieved to cause resultant desirable physical effects in the flowable (typically liquid) repair material.

The vibration means preferably comprises ultrasonic vibration means desirably operating substantially in the range 20KHz-150KHz (more preferably substantially in the range 35KHz-55KHz). The vibration means therefore preferably comprises ultrasonic vibration means arranged to effect vibration substantially in the range 20KHz- 150KHz (more preferably substantially in the range 35KHz- 55KHz). The ultrasonic vibration means preferably includes an ultrasonic transducer.

The vibration means is preferably applied in the region of

the flaw or void. Desirably the probe is tracked along the direction of an elongate flaw or void (crack).

In one embodiment, the vibration means may be hand held and manipulated digitally by an operative.

The rigid vibration delivery probe preferably includes a contact surface or tip for contacting the body or other vibration transmission medium.

The rigid vibration delivery probe preferably comprises an elongate rigid probe extending from a high frequency generator to the contact surface or tip. The distal contact portion or tip of the rigid material probe is typically of smaller sectional area relative to a portion of the probe less distal. The cross sectional area of the contact surface or tip is preferably at or below 1 cm2 (more preferably at or below 0.5cm2).

The technique is particularly useful where the flaw comprises a crack, break, pit or discontinuity in the material of the body connecting to a surface of the body, especially where the body comprises a sheet of material, particularly a glazing or window element.

The repair material preferably comprises a flowable repair material such as a fluid or the like, desirably a viscous fluid such as a resin. The repair material preferably has optical qualities (when hardened) substantially matching optical properties of the body. Desirably, the body is substantially transparent at least to one or more

wavelengths of visible light.

In one embodiment, the repair material is first applied to at least partially penetrate the flaw or void, the vibration means being subsequently applied to effect enhanced penetration of the repair material into the flaw or void. Alternatively, the repair material and the vibration means may be applied contemporaneously.

In one embodiment, the repair material may be applied to the region of the flaw or void, a cover position over the repair material and the vibration means applied to act on the body. The vibration means may be applied directly to the cover, or, alternatively, the cover may be positioned to overlay an obverse surface of the body, the vibration means being applied to a reverse surface of the body. As a further alternative, the vibration means may be applied to a reverse surface or applied directly to the repair material in situ without utilisation of a cover.

In a preferred embodiment, the vibration means is applied adjacent the flaw or void, advantageously at a level below the flaw or void. A coupling material (such as a coupling gel) may be applied to the body for enhanced vibration transmissive coupling of the vibration means.

According to a further aspect, the invention provides a kit for repairing a flaw or void in a body, the kit including: i) apparatus as herein defined; and,

ii) repair material for infilling the flaw or void.

The apparatus may further include a cover sheet or strip for covering the resin in situ in the flaw or void and/or a vibration coupling material.

By providing high frequency vibration for the body to be repaired, the mechanical vibration of the body aids in effecting full penetration of the repair material into the flaw or void. Furthermore, where the repair material is a fluid or gel (such as a resin), the applied high frequency vibration acts to reduce the viscosity and promote flow of the repair material. De-gassing of such repair material is also promoted by the ultrasonic vibration which results in a superior optical quality repair.

The invention will now be further described in specific embodiments by way of example only and with reference to the accompanying drawings, in which: Figures 1 to 6 show alternative embodiments of repair technique in accordance with the invention; Figure 7 is a schematic side view of an alternative embodiment of apparatus for performing the techniques of figures 1 to 6; and Figure 8 is a schematic exploded perspective view of apparatus similar to the apparatus of figure 7.

Referring to the drawings a laminated vehicle windscreen 1 has an elongate crack running across a portion of the screen 2 communicating with the upper surface of the windscreen, which is consequently in need of repair. In accordance with the invention, liquid resin 3 is applied to the region of the crack 2 and a tip 4 of a titanium probe of an ultrasonic applicator head 10 is applied to induce high frequency vibration to act on the windscreen 2 and resin 3 in order to aid penetration of the resin into the crack 2.

The ultrasonic probe tip 4 is operated to produce high frequency vibration at a vibration frequency of 40kHz.

This frequency has been found to produce optimum results, although the technique is believed to be operable with frequencies in the range 20-150KHz (particularly in the range 35-55KHz). Lower frequencies in the range specified permit the required energy to be delivered but minimise coupling losses. The head 10 includes an ultrasonic transducer 5 and a removable probe tip in the form of horn 4. For repairing the elongate crack 2 the probe tip is traversed along the crack, preferably manually by hand or alternatively in conjunction with a guide support frame (see later).

In the arrangement shown in figure 1 the probe tip 4 is applied directly to contact a bead of resin 3 overlaying (and partially penetrating) the crack 2.

In a preferred embodiment shown in figure 2, repair resin in liquid form is applied to a length of crack 2 and a a

flexible sheet or strip of a plastics material (such as commercially known Mylar film membrane) 6 is placed against the screen surface to cover the resin 3 in the length of crack 2. The plastics strip or sheet 6 is secured to the screen 1 by means of adhesive tape (to produce a sealed pocket about the resin in crack 2).

Alternatively, an adhesive may secure the plastics sheet or strip to the screen 1. The plastics strip or sheet may be adhesive backed for this purpose. Sealing of the sheet or strip to the windscreen surface reduces the amount of oxygen entering the resin which aids in providing a crack repair having optimum optical qualities.

The ultrasonic vibrator probe tip 4 is placed in contact with the plastics sheet or strip 6 to form a barrier between the resin 3 and probe tip 4, but which still permits vibration transmission between the probe tip 4 and the resin and windscreen 1. The probe tip 4 is preferably applied to the strip 6 (or possibly directly to the windscreen surface) at a position adjacent to, and preferably below, the crack 2 (the position denoted by arrow X in figure 2. The horn tip is then drawn along a line following the line of the crack 2.

In the embodiment in figure 3 resin is delivered via an external conduit 7 extending along the length of probe tip 4 to exit via an aperture in the probe tip 4 directly into crack 2. Ultrasonic vibration of probe tip 4 results in at least partial atomisation of the resin flowing along conduit 7 which aids in penetration into the crack 2.

In the embodiment shown in figure 4, the resin is placed in contact with the outer surface of the windscreen 1 but the probe tip 4 of the ultrasonic vibration apparatus is placed in contact with the reverse face of the windscreen adjacently crack 2.

In the embodiment shown in figure 5, the arrangement corresponds to that shown in figure 4, however a Mylar film membrane 6 is placed over the resin (to minimise oxygenation) and an ultrasonics coupling material 8 (such as a coupling gel or plastics or rubber mat) is placed between the probe tip 4 and the reverse face of the windscreen 1. The coupling material 8 aids in transmission of high frequency vibration from the probe tip 4 to the windscreen 1. Such a coupling material can be utilised for any of the embodiments described herein.

In the embodiment shown in figure 6, the ultrasonic vibrating apparatus 10 is mounted by means of an arm 9 to a suction cup 11 which adheres to the outer surface of windscreen 1. Various suction/vacuum arrangements for securing the vibration head 10 to the windscreen are envisaged and such embodiments are disclosed in, for example, the prior art references referred to on page 1.

Additionally, the head 10 can be movable relative to the support arm 9 toward and away from the windscreen 1 (for example by being screw thread mounted on arm 9) permitting the tip of horn 4 to be advanced toward the windscreen for pressing the resin 3 into crack 2 and subsequent retraction away from the windscreen.

Referring to a preferred embodiment of apparatus shown in figure 7, the probe comprises an elongate metallic probe 15, having a tip 16 arranged to contact the windscreen or the plastics sheet or strip 6 (or the resin directly).

The elongate probe 15 extends from a pistol shaped housing 17, having a handle grip 18 for manipulation by the user.

The housing 17 contains an ultrasonic transducer and the power supply is provided by a remote powerpack 20 (connected by an umbilical 19) which is provided with a clip 22 for mounting the powerpack to an item of the users clothing (such as a belt). The apparatus is operated to deliver ultrasonic vibration via probe tip 16 by operation of trigger 25.

Separation of the powerpack 20 from the transducer housing 17 and probe 15 enables the apparatus to be more conveniently manipulable. In the technique shown in figure 7, the probe tip 16 is applied directly adjacently beneath the elongate crack 2 (running in a direction into and out of the paper) and tracked along the windscreen 1 adjacent the crack 2.

For any of the embodiments described, the ultrasonic probe tip 4 may revisit part of the crack 2 (where air may remain trapped in the resin) following initial application. Resin within the crack 2 is subsequently cured in a conventional manner using UV activation or by any other suitable curing means depending on the particular resin being utilised.

Referring to figure 8 a most preferred embodiment of

apparatus according to the invention is shown. Similarly to the embodiment of figure 7, the apparatus comprises a hand manipulatable probe unit 126 and a separate power control unit 120, the respective units being connected by a flexible power connection line (umbilical) not shown.

The probe unit includes an ultrasonic generator stack 127 connected to a coaxially aligned elongate titanium sonotrode probe 115. The probe reduces in diameter toward the distal tip end in order to enhance the vibration delivery characteristics at theip 116. The probe unit includes a handle extension 118 extending transversely to the axial direction of the probe 115, and is provided with a switch 125 enabling operational triggering of the ultrasonic generator 127.

The power control unit 120 includes a support chassis 129 for supporting electronic control and power circuitry.

Parameters of operation can be set by means of controls such as the amplitude adjustment control 130. A belt clip 131 is provided permitting the power control unit 120 to be mounted onthe belt or other apparel of an operative.

The invention provides that, by using high frequency vibration delivered by the ultrasonic horn 4, the resin viscosity decreases permitting more free flow into the crack (this is aided, particularly, where the ultrasonic vibration is used to atomise the resin); furthermore, high frequency vibration of the material comprising the laminated windscreen aides in permitting penetration of the resin into the crack 2. The ultrasonic vibration also

acts to disperse air bubbles present in the resin, and hence produce a repair of maximum optical quality finish.

Following removal of the high frequency, the resin viscosity returns to substantially its original value almost instantly.

Following curing of the resin, any excess resin around the crack on the outer surface of windscreen 1 may be removed using conventional (typically abrasive) techniques.