FR2724896A1 - Device for setting vehicle windscreen wiper wiping force - Google Patents

Abstract

The coil spring (10) is designed as a series of coils (14) of wire wound in a helix and is terminated at the ends by hooks (16), by which it is attached to the wiper drive head assembly at one end and the wiper arm at the other end. The spring mechanism is designed to allow adjustment of the cleaning force applied by the windscreen wiper arm to the windscreen. The spring is formed as at least one section (12) of spring with an element (22) to allow adjustment of the value of the tare of the spring force. The adjustment element consists of a threaded body (20), which is screwed into the internal bore of the helicoidal section (12) of the spring, in such a way as to allow the effective length of the spring to be adjusted.

Description

 The present invention relates to a spring for setting the wiping force of a wiper.

 The invention relates in particular to a calibration spring for a wiper of the type comprising a wiper arm which carries at least one wiper blade and which is mounted articulated about a hinge pin, on a wiper arm drive head.

 The drive head is driven in an alternating rotational movement by a wiping shaft, also called a drive shaft, in order to obtain a sweeping of the window to be wiped.

 The wiper arm carries a wiper blade which is articulated and which is capable of wiping the glass surface, such as for example a vehicle windshield.

 In order to obtain an effective wiping of the glazed surface, it is necessary that the wiping blade of the wiper blade is applied to the glazed surface to be wiped with a sufficiently high pressure or wiping force. .

 For this purpose, it is known to provide at least one coil type spring, also called helical, compression or tension spring, which is arranged between the drive head and the wiper arm and which applies to the latter a force whose straight support is not concurrent with the axis of articulation of the wiper arm on the drive head so as to apply a wiping torque to the wiper arm, also called nominal wiping torque, the value of which is substantially constant.

 Due to the design of this device, the wiping blade is pressed during the scanning movement of the glazed surface.

 It is easy to understand that the quality of the wiping depends on the initial setting of the value of the wiping torque and that this value depends essentially on the characteristics and dimensions of the various components, and mainly on the elastic constant of the spring, as well as on the precision of the assembly carried out.

 Furthermore, it is necessary to have a range of wipers, according to the different types of vehicles, as well as according to the different models of the same vehicle, the characteristics of which vary, and in particular the value of the wiping torque.

 It is also particularly important, for the same model or the same type of vehicle, to ensure a constant value of the wiping torque whatever the spring which is fitted.

 Furthermore, the mass production of springs all having reliable and constant characteristics is particularly difficult.

 The object of the present invention is to propose a new design of a spring for calibrating the wiping force which makes it possible to remedy the drawbacks which have just been mentioned.

 For this purpose, the invention provides a spring for calibrating the wiping force of a windscreen wiper, of the flange type, characterized in that it is produced in at least one section of spring and at least one member. adjustment assembled in an adjustable way to vary the setting value of the spring.

According to other features of the invention
- the adjustment member comprises a threaded body which is screwed in an adjustable manner on a helical section of the spring
- the threaded body is screwed in an adjustable manner inside the helical section
- The adjustment member comprises two opposite threaded bodies, each of which is screwed in an adjustable manner in one end of a helical section, the other end of which comprises means for hooking the spring.
- the threads of the two threaded bodies have opposite directions;
- the adjustment member comprises, between the two threaded bodies, a gripping section to drive it in rotation
- the threaded body is extended by means of hooking the spring
- the spring has a helical section and, at each of its ends, a hooking portion screwed in an adjustable manner
- the spring is a tension spring.

Other characteristics and advantages of the invention will appear on reading the detailed description which follows for the understanding of which reference will be made to the appended drawing in which
- Figure 1 is a view, in partial axial section, of a first embodiment of a tension spring produced in accordance with the teachings of the invention
- Figure 2 is a view similar to that of Figure 1 which illustrates a second embodiment; and
- Figure 3 is a view similar to that of Figure 1 which illustrates a third embodiment of a calibration spring according to the teachings of the invention.

 The spring 10 illustrated in FIG. 1 is a tension spring which is a spring for setting the wiping force of a wiper (not shown) which is adjustable.

 In this first embodiment, the tension spring 10 is a coil type spring which is produced in three parts.

 The spring is essentially constituted by two sections of springs 12 each of which consists of a series of turns 14.

 The helically wound wire constituting the turns 14 of each section 12 of the spring 10 ends at one of its ends by a loop 16 allowing the spring to be hooked.

 At its other end 18, formed by the end of a turn 14, each spring section 12 is mounted screwed onto a threaded body 20 belonging to a part 22 constituting the member for adjusting the spring setting force.

 The adjusting member 22 is made in a single piece with a knurled central part 24 which allows it to be rotated around its main axis along which the two threaded bodies 20 are aligned.

 As can be seen in FIG. 1, the pitches of the two threaded bodies, respectively to the left and to the right of the central knurled portion 24, are reversed so as to allow simultaneous movement and in the same direction, in approach or in distance of the knurled central part 24, of the two sections 12 of the spring 10 when a rotation is applied to the knurled central part 24.

 As shown in FIG. 1, the spring 10 has a minimum length, the end turns 18 being in abutment against the opposite lateral faces 26 of the knurled central part 24.

 The length, and therefore the setting force of the spring 10, is adjusted by causing the threaded bodies 20 to rotate, which are mounted screwed inside the sections 12 of the spring.

 The design according to the invention makes it possible, by producing sections of spring 12 separately and assembling them using an assembly and adjustment member 22, to produce springs 10 of lengths, and therefore of elastic constants, different without requiring a large stock of a series of springs in one piece, as in the prior art.

 The setting of the setting value of the spring 10 can be carried out in situ once hung on the windscreen wiper or before it is hung using a length adjustment jig (not shown), or on a bench. measurement of its taring force (not shown).

 In the second embodiment illustrated in FIG. 2, in which elements identical or similar to those of FIG. 1 are designated by the same reference numbers, the spring 10 comprises a single section of spring 12 with turns 14 which ends by a hooking loop 16 and the assembly and adjustment member 22 is constituted by a single threaded body 20 which is screwed to the end 18 of the helical section 12 and which ends in a loop-shaped end 16 produced integrally with the threaded body 20.

 The grip part 24 of the first embodiment is replaced by the loop 16 proper which allows the threaded body to rotate in relation to the section 12 of the spring 10.

 As in the case of the first embodiment, the setting of the spring setting is carried out by varying the overall length of the assembly, that is to say the length of the section of the threaded body 20 which is fixed to the inside the turns 14 of the section 12 of the spring 10.

 Finally, in the third embodiment illustrated in FIG. 3, the section of helical spring 12 with turns 14 is open at its two ends 18 and each receives a threaded body 20 which, as in the case of the second embodiment illustrated in FIG. 2 ends with a hooking loop 16.

 Unlike the first embodiment illustrated in FIG. 1, the thread pitches of the threaded bodies 20 can be in the same direction, the threaded bodies 20 being screwed independently of each other inside the coil spring section 12 .

 The length and the setting value of the spring 10 are adjusted as in the case of FIG. 2 by screwing, more or less, the threaded bodies 20 inside the section 12.

Claims (9)

 1. Spring (10) for calibrating the wiping force of a windscreen wiper, of the flange type, characterized in that it is produced in at least one spring section (12) and at least one adjustment (22) assembled in an adjustable manner to vary the setting value of the spring (in).  2. calibration spring according to claim 1, characterized in that the adjusting member (22) of the spring comprises a threaded body (20) which is screwed in an adjustable manner on a helical section (12) of the spring (10).  3. calibration spring according to claim 2, characterized in that the threaded body (20) is screwed in an adjustable manner inside the helical section (12).  4. calibration spring according to claim 3, characterized in that the adjustment member (22) comprises two opposite threaded bodies each of which is screwed in an adjustable manner in one end (18) of a helical section (12) of which l 'other end comprises means (16) for hooking the spring.  5. calibration spring according to claim 4, characterized in that the threads of the two threaded bodies (20) are in opposite directions.  6. calibration spring according to one of claims 3 or 4, characterized in that the adjustment member (22) comprises, between the two threaded bodies (20), a section (24) for gripping to drive it in rotation.  7. calibration spring according to one of claims 2 or 3, characterized in that the threaded body (20) is extended by means (16) for hooking the spring (10).  8. calibration spring according to claim 7, characterized in that it comprises a helical section (12) and, at each of its ends (18), a hooking part (16, 20) screwed in an adjustable manner.  9. calibration spring according to any one of the preceding claims, characterized in that the spring (10) is a tension spring.