FI60311B - VID ETT FORDONSHJULNAV FAEST ANORDNING FOER REGISTRERING AV DEN AV FORDONET TILLRYGGALAGDA VAEGSTRAECKAN - Google Patents

Description

ΓβΙ / 111 NOTICE OF PUBLICATION, ΓΐΊΛΛ (11) UTLÄCGNINGSSKRIFT 6031 I

Patent laollelat ^ ^ '(51) Kv.lk?/lnt.CI.3 G 01 C 22/00 SUOMI — FINLAND (21) P * tanttlKak «mu · - Patcntansfiknlnj J6 3076 (22) HakmntapUvI - AntBknlngtdif 28.10.76 ( 23) Alkupitvi — Glttlghatadif 28.10.76 (41) Tullut luikikuksi - Bllvlt offantilg 20.08. 77

Patent and Registration Office ......... , . ,. . . . . . (44) Date of issue of the publication. - Q o-,

Patent-och registerstyrelsen Anattkan utlagd och uti.tkrift «n pubikiind 31 · 08.81 (32) (33) (31) Requested atuolkaut — Begird prloritat 19 * 02.76

Sweden-Sverige (SE) 7601903 “3 (71) Record Taxameter AB, Box l66, S-301 0U Halmstad, Sweden-Sverige (SE) (72) Lennart Borgström, Svängsta, Sweden-Sverige (SE) (7 ^ *) Berggren Oy Ab (5 * 0 Device for recording the distance traveled by a vehicle wheel hub - Vid ett fordonshjulnav fäst anordning för registration av den av fordonet tillryggalagda vägsträckan

The invention relates to a device mounted on a wheel hub of a vehicle for recording the distance traveled by the vehicle, the device comprising a counter, a stamping card stamping mechanism and feeding means for advancing the counter wheels as a function of distance, feeding means actuating means consisting of an annular pendulum and a pendulum pendulum coupling members formed by a screw on the shaft to the feed members of the counter wheels.

Feeding means for progressively feeding the counter wheels comprise a feed arm adapted to perform a pivoting movement in an arbitrary direction of rotation between two stable end positions of the helical wheel, depending on the rotation of the helical wheel, by rotating the feed arm

The wheels of the calculator have embossed number letters for stamping stamp cards. As a result, if a thin is inserted into the card slot.

2 £ 0311 suitably bent plate and this is pressed against the embossed letter, this letter is pressed back. With skillful handling, it is thus possible to make the counter display a shorter distance than the distance actually traveled by the vehicle.

The object of the present invention is to make such fraud against devices (odometers) mentioned at the beginning impossible. The feed means of the device comprises, for each number wheel, a transmission wheel rotating on the drive axis parallel to the wheel axis of the counter, located between the wheels of said pair and in engagement with them, for feeding a pair of higher signage number wheels one lower order per lower sign. The invention is essentially characterized in that the drive shaft is held at its end on the same side as the most significant numeric wheel of its counter by a resilient retaining member that at least the toothing between the most significant number wheel wheels and the corresponding transmission wheel ceases. The number bookswheels then give a stamp consisting of disordered integers, half-digits, and smaller parts of the numbers, so that the irrelevant operation is easily exposed.

In a device according to the invention with a common shaft lock which engages a groove at one end of a drive shaft inserted into a common hole in the body of the device for radial and axial holding of this end, the resilient member may be a groove rider which engages at one end of the groove drive shaft into an elongated hole in the body. The elongate hole may then consist of two overlapping, circular hole portions, the first of which has a diameter adapted to the diameter of the drive shaft to receive the end of this shaft without play, while the second part has a considerably larger diameter to receive said end with large play. The slotted rider may further be a recessed disc rider having a circular arc-shaped portion in the center of the inner edge of each leg, with the shape and spacing of both portions adapted to receive and hold the respective drive shaft end against axial and radial motion, wherein the rim has an upwardly bent portion adapted to engage a groove in the body of the device, and the resilient properties and dimensions of the rider and the dimensions of the axle groove are such that when a radial or axial force exceeding a predetermined value acts on the axle, the shaft end loses grip and is radially to an undefined position in the elongate slot.

The invention will be explained in more detail in connection with the exemplary embodiment shown in the accompanying drawing.

Figures 1 and 2 show the input mechanism of the number letter wheels of the device according to the invention, Figure 2 showing a section V-V of Figure 1. Fig. 3A shows details of the feed members from above, and Figs. 3B and 3C show sections Y-Y and X-X of Fig. 3A, respectively. 4A and 4B are two orthogonal views of a groove rider of a device according to the invention. Figure 5 shows, on a larger scale, a shaft hole for the other end of the drive shaft supporting the drive wheels of the number book wheels. Figure 6 shows the latter axis.

Initially, the feed mechanism of the numeric bookwheels of the counter will be explained in connection with Figs.

The first part of the transmission system for transmitting the continuous movement of the helical wheel 10 to the number wheels 19 consists of a crank mechanism. At the opposite end of the shaft 42 supporting the helical wheel 10 is a plate 28 with a crank pin 29. The crank pin 29 acts on the bearing arm 30 via a groove 31. The palm arm swings back and forth between its end positions regardless of the direction of rotation of the helical wheel 10. At the end opposite the groove 31 of the palm arm there are outwardly bent crank strips 32 which act on the feed arm 33 via a riveted stop 34 thereon. The feed shaft 33 is mounted on the shaft 35 and can oscillate between the outline of the two feed arms 33 and the end position determined by the mating pin 36. In addition, a feed spring 37 and a spring support 38 are attached to the feed arm 33. The feed spring 37 acts on a retaining wheel 53 arranged on the side of the first number book wheel 19, which rotates on the shaft 54 of the landing wheel.

4,60311

The feed arm is also acted upon by a spring support 38 suspended by a lock spring 39 suspended at one end from the support 40. The feed arm 33 can be positioned in two stable positions, namely ready to feed the retaining wheel 53 from the tooth 41 next to the first number wheel 19, and to a second position where the end arm 33B rests against its abutment 36. In this second position, the locking spring 39 is unloaded and the tooth 41 has moved forward one position.

By making the clearance between the crank strips 32 and the stop 34 suitable (Fig. 2), a forced feed of the feed arm is provided between the stop pin 36 and the two extreme positions determined by the end arms 33A and 33B. This forced feed is not used in normal use, as the locking spring causes the feed arm to slowly rise to the dead position, after which it snaps into stable extreme positions. If the snap movement is prevented for any reason, e.g. due to ingress of dust or dirt, increased friction or inappropriate means for braking the wheels inside the mechanism, the forced feeding of the number wheels will nevertheless continue and thus the distance traveled will also be reduced.

If the number wheels are braked so that they come to a complete stop, the feed spring 37 is overloaded and changes its shape permanently, so that the further feeding of the number wheels does not take place even after the stop stops.

The stamping card is stamped from the numbering wheels 19 through an opening 64 in the second wall 63 of the card slot 4 or from the numbering wheels 19A, which are fixedly positioned and together form the device number of the device, through the opening 64A.

As can be clearly seen in Figures 3A and 3B, the odometer comprises number book wheels 19 rotating on shaft 54. Transmission wheels 62 rotating on shaft 55 are arranged between the retaining wheel 53 and the first number book wheel A and further between each pair of number dial wheels A-B, B-C, B-C, B-C, B-C. The letters 57 of the number book wheels are raised and are intended to affect the stamp card inserted through the opening 64 (Fig. 3B) into the card slot 4 60311 during stamping. The dial 54 has a fairly large diameter to provide a neat stamp. The friction torque is then quite large, but to counterbalance it, the drive shaft 55 has a small diameter, so that the friction torques are kept low. Each transmission wheel 62 has a hub 65, a set of teeth 66 of five teeth 68 integral therewith, and a second set of teeth 67 of ten teeth 69 integral with the latter. pulses once per revolution per revolution the numerically lower dial pad or the holding wheel to gradually move the decimals upwards in the counter. The one-step operation is such that the set of gears 67 is toothed into the set of teeth 71 of the numeric letters. The dials are graded 0-9 and Fig. 3A shows the number 765422 in the stamping position. The wheels 19 have the markings A, B, C, D, E and F in Fig. 3A, as mentioned above, and show maximum values of 9, 99, 999, 9999, 99999 and 999999 km.

Figure 3B shows how one could think of a procedure for unauthorized alteration of the numerator count. With a suitably bent plate 56 inserted into the card slot 4 against the raised number 57, this number can be forcibly pressed back so as to obtain a lower number reading. In practice, the treatment of low-mileage wheels A, B, C is of little relevance. Wheels D, E, and F, on the other hand, are very important, which is why handling them is worth some effort.

Figure 3B shows two intersecting lines at the center of the drive shaft 55, one passing through the alignment point between the plate 56 and the numeric booklet 57 and the other passing through the center of the shaft 54. These lines form a small angle L between them and the latter line indicates the direction of the force P acting on the drive shaft 55, which becomes quite large when a fairly moderate force is applied to the plate 56.

In order to prevent this possibility of handling numbered letters, the invention proceeds in such a way that the drive shaft 55 springs outwards due to the force P, i.e. in Fig. 3A the upper end 74 pivots out the jaws 71 lose their grip on the gears 62. This means that the wheels 62 no longer lock the gears 19, which are thus released to perform an uncontrolled movement and thus settle into uncontrolled positions. This is reflected in the stamping in that certain numbers are only partially reproduced, thus directly revealing the processing performed. In addition, the arrangement must be such that the counter can be restored to a working condition only by means of a repair carried out at the factory.

More specifically, said flexibility of the shaft 55 is provided as described below. Shaft 55 has an annular groove 61 near both ends (Figure 6). The shaft end 72 (Fig. 3A) supports a common shaft lock 59 in the groove 61, which abuts the side wall 73 of the body and is inserted into a common hole in this wall. At the other end 74 of the shaft, a special groove assembler 58 (Figures 4A and B) is attached to the groove 61, which is adapted to rest against the inner side of the side wall 75. The other end of this rider 58 is bent upward at 76 (Fig. 4A) and this end is inserted into a groove 77 in the wall 75 (Fig. 3C). As shown in Figure 4B, the rider 58 has a specially shaped recess 78, a portion 79 of which is adapted to fit against the base of the groove 61 in the shaft 55. The longitudinal line of symmetry of the recess 78 extends in the rolling direction of the rider's plate material. The hole 60 in the side wall 75 for the shaft 55 has a special shape, as shown in Fig. 5. It consists of a part 80A having a diameter adapted to the diameter of the shaft 55 and an associated part 80B having a considerably larger diameter. The shape of the hole 60 is roughly similar to a keyhole and its contour roughly corresponds to the outline of the number 8, whereby the second loop of this number is considerably larger and the loops are as if pressed into each other. The normal position of the shaft end 74, the rider 58 and the hole 60 is shown in Figure 3C. The head 74 is then located in the smaller portion 80A of the hole 60 when tightened by the rider 58.

If, as shown in Fig. 3B, the plate 56 is pressed against the booklet 57, the gripping force of the rider 58 against the shaft 55 is overcome due to the relatively large force P so that the shaft end 74 snaps away from the rider 58 and thus fits into the larger portion 80B of the hole 60. This results in the tooth loss described above

Claims (4)

7 60311 at least between the wheels D, E, F and the corresponding gear 62, whereby an irrelevant operation is definitely revealed. The locking force of the groove rider 58 against the shaft 55 is, of course, adapted so that the shaft 55 cannot snap off in the event of shocks and bumps which may be expected to occur in normal use of the odometer. In the installation, the shaft 55 is inserted into the hole 78, in which case the groove rider is not subjected to deformation forces. The groove rider is further made such that the relatively small radial displacement of the shaft 55 causes it to snap away from the groove rider. The rigidity of the latter is such that snapping requires a slight bending of the rider's arms outwards, while maintaining the desired locking force during normal operation of the meter. The device shown can be modified in various ways within the scope of the claims. A device for recording the distance traveled by a vehicle wheel hub, the device comprising a counter, a stamp card stamping mechanism and feed means for feeding the counter wheels as a function of distance, feed means actuating means consisting of an annular pendulum with a helical wheel and a helical wheel coupling means for feeding the counter wheels, wherein the feed means for gradually feeding the counter wheels further comprises a feed arm adapted to perform an arbitrary turning direction depending on the rotation of the helical wheel. , and wherein the feed means for each pair of number book wheels comprise a counter wheel axle su a drive shaft rotating on the sleeping drive shaft, located between the wheels of said pair and engaging with them, for feeding a pair of higher significance numerical dial wheels one degree lower for each revolution of the numerical dial wheel of lower significance, characterized in that its drive shaft (55) holds the drive shaft (55) (F) with a resilient retaining member (58) at the end of the racket side, adapted to resiliently release and release said end (74) by at least one radial force acting on said shaft (55), thereby performing a second pivoting movement of the shaft (55) when the head (72) acts as a center of rotation, that the toothing between at least the most significant number books (D, E, F) and the corresponding transmission wheel (62) ceases. A device according to claim 1, having a common shaft lock (59) engaging a groove (61) at one end (72) of the drive shaft (55) inserted into a common hole in the body of the device for radial and axial locking of this end, characterized in , that the resilient member is a groove rider (58) which engages a second groove (61) at the other end (74) of the drive shaft which is inserted into an elongate hole (60) in the body of the device. Device according to claim 1 or 2, characterized in that the elongate hole (60) consists of two overlapping, circular hole parts, the first (80A) having a diameter adapted to the diameter of the drive shaft to receive the end (74) of this shaft without clearance, while the second part (80B) has a considerably larger diameter for receiving said end with a large clearance after the resilient member (58) has been triggered. Device according to Claim 2 or 3, characterized in that the groove rider (58) is a disc rider with a recess (78), the central part of the inner edge of each leg having a circular arc-shaped part (79), the shape of both parts (79) and the mutual distance is adapted to receive and hold the end (74) of the respective drive shaft against axial and radial movement, the rider (58) having an upwardly bent portion (76) at the edge opposite the recess opening adapted to engage a groove (77) in the body of the device, in addition, the resilient properties and dimensions of the rider (58) and the dimensions of the shaft groove (61) are such that when a radial or axial force exceeding a predetermined value acts on the shaft (55), the shaft end loses grip and settles radially and axially indeterminate in the elongate hole ( 60). 6031 1