The load carrier comprises a longitudinal rail section provided with connecting devices for connection to the said mounting devices and securing devices for securing the wheels of the bicycle loaded on it, a retaining arm pivotably arranged relative to the rail section and provided with a claw grip consisting of a first and a second jaw, which jaws are positioned laterally with respect to the longitudinal direction of the rail section and arranged so that they form a gap facing the side of the longitudinal rail section from which the bicycle is loaded, and which retaining arm is arranged to pivot so that it can be turned to a position in which the claw grip can be attached to the frame of the loaded bicycle when the said bicycle is in the upright position, and in which position the claw grip can be tightened around the frame to hold the bicycle in the said upright position.

State of the art Load carriers of the type described above are common. These include those described in the applicant's application SE 9302881-9, as well as in US 4,702, 401 and WO 01/38141. The disadvantage of these earlier load carriers, however, is that they afford a loaded bicycle insufficient support to prevent it from falling before the claw grip is securely attached to the frame. This requires the person loading the bicycle to use one arm to ensure that the bicycle does not fall, with the result that only one arm is free to attach the claw grip to the frame, which can be very difficult, especially when the claw grip itself requires several actions to attach it securely. In WO 02/18177, this has been solved by providing the rail section in the area of the front wheel of the bicycle with a trough, in which the wheel is placed, providing the bicycle with sufficiently stability to remain upright in the rail section without support other than that provided by the said trough. However, the disadvantage of this solution is that since there exist bicycles with varying wheel widths, it may easily happen that a bicycle wheel does not fit in the trough because the wheel is too wide or that the bicycle is not afforded support because the wheel is too narrow.

A further disadvantage of earlier load carriers is that the bicycle wheels may easily be placed outside the rail section when loading the bicycle on the load

carrier, since the rail section is narrow, and when the bicycle is difficult to lift onto the load carrier when the latter is mounted on a vehicle roof. This disadvantage is especially noticeable when the person lifting the bicycle is either short or weak, which is often the case when the person lifting the bicycle is a child or a woman.

Yet another disadvantage of earlier devices is that the claw grip is so arranged that it must be adjusted to the open position by the user before it can be attached to the bicycle frame, which may easily present the user with problems if he forgets to adjust the device to the open position before placing the bicycle on the load carrier. Thus, previously mown load carriers suffer from a large number of disadvantages which make it difficult, and sometimes impossible, to load a bicycle on them without damage to the vehicle on which the load carrier is mounted when the person loading the bicycle is not sufficiently tall relative to the vehicle or possesses insufficient bodily strength.

Problem Thus, there exists a need for a load carrier of such design that it affords a solution which overcomes the disadvantages of previously mown load carriers and on which it is easy to load a bicycle.

Summary of the invention The present invention overcomes the said disadvantages by means of a load carrier of the type described above, which is characterised in that the longitudinal direction of the rail section, in the area of one wheel of a bicycle loaded on it, is arranged at an angle relative to the longitudinal direction of the rail section in the area of the second wheel of the bicycle loaded on it, causing the bicycle to move along the rail section and causing the frame of the bicycle to enter into active engagement with at least one of the jaws of the claw grip, thereby ensuring that the bicycle remains in the upright position even when the claw grip is not tightened.

The present invention is further characterised in that the angle in question is between 179 and 160 degrees.

The present invention is yet further characterised in that the angle in question is between 175 and 165 degrees.

The present invention is yet again further characterised in that the angle in question is between 174 and 172 degrees.

As an alternative, the present invention affords a load carrier of the type described above, which is characterised in that the claw grip is acted on by an

elastic element, which ensures that the claw grip is held in the open position when it is not adjusted to the tightened position.

As a further alternative, the present invention is characterised in that the elastic element consists of a coil spring.

As yet a further alternative, the present invention is characterised in that at least one of the jaws is provided with a recess extending essentially parallel to the longitudinal direction of the rail section.

In addition, the present invention is characterised in that the securing devices include a cradle mounted to the rail section, which cradle is U-shaped in cross- section, one flange of the U being higher than the opposite flange and the higher flange being located on the side of the rail section opposite to that from which the bicycle is loaded.

Brief description of figures The above characteristic features and further advantageous features will be clear from the following description of a preferred embodiment as illustrated in the appended figures, of which: Fig. 1 is a view of a load carrier in accordance with the present invention, showing a bicycle which is loaded and mounted on a vehicle roof, with the claw grip and securing devices untightened; Fig. 2 is a view corresponding to Fig. 1, showing the claw grip and securing devices in the tightened mode; Fig. 3 is a general view of a load carrier in accordance with the present invention mounted on mounting devices ; Fig. 4 is a detail view of a retaining arm forming part of the invention; Fig. 5 is a view through section C-C in Fig. 4; Fig. 6 is a view through section D-D in Fig. 3 of one of the securing devices forming part of the invention, , and Fig. 7 is a detail view of a tightening device attached to the retaining arm.

Preferred embodiment Figs. 1 and 2 show a load carrier 1 loaded with a bicycle 2. The load carrier is mounted on a vehicle roof 4, which is shown only schematically in the figures, by means of mounting devices 3. A longitudinal rail section 5 forming part of the load carrier is also shown in the figures. The rail section is provided with securing devices 6 for securing the front wheel 7 and the rear wheel 8 respectively of the bicycle to the rail section when the bicycle is loaded. The longitudinal direction of the rail section in area 9, on which the rear wheel of

the bicycle is placed, is indicated by the dash-dotted line A-A and the longitudinal direction 10 of the rail section in the area on which the front wheel of the bicycle is placed is indicated by the dashed line B-B, the intersection of which lines forms an angle a. The effect of this angular relationship between areas 9 and 10 is that a bicycle placed on the rail tends to move in the direction of the longitudinal direction of the rail section. Given the relationship shown in the figures, the bicycle tends to move in the direction indicated by the arrow F in Fig. 1. Should area 9 be angled in the direction opposite to that shown in the figures, the bicycle will, as will clearly be seen, tend to move in the opposite direction to the arrow F. It will further be clear to one skilled in the art that the angled area may equally well be located in the area on which the rear wheel 8 of the bicycle is placed in order to achieve this effect of movement.

Fig. 3 shows the load carrier 1 in detail. The figure shows the mounting devices 3, which comprise a first load carrier foot 11 and a second load carrier foot 12 designed for attachment to the vehicle roof, which is not shown in the figure. Each pair of load carrier feet 11 and 12 respectively supports a load carrier bar 13 on which the rail section 5 is mounted in a known manner by means of connecting devises 14 and 15 respectively. A retaining arm 16 is, in known manner, connected to the rail section 5 in a pivoting manner and can be pivoted in the direction indicated by the double arrow P. The friction of the pivoted mounting is, in known manner, designed so that the arm remains in the position to which it is adjusted, regardless of that position. In the figure, the retaining arm is attached to the connecting device 15, although it will be obvious to one skilled in the art that the arm may equally well be attached in pivoting manner to the rail section 5 or to the load carrier bar 13. The retaining arm 16 is provided with a claw grip 17 consisting of a first jaw 18 and a second jaw 19 whose function will be described below. The longitudinal direction of the jaws is indicated by the arrow T and, as shown in the figure, this direction is lateral to the longitudinal direction of the rail section as indicated by the arrow L. The jaw 18 is provided with a recess 20, whose direction is indicated by the arrow 1 and whose direction is essentially parallel to the direction L. The function of the recess will be described below.

Figs. 4 and 5 show the retaining arm 16 in detail. As the figures show, the arm consists of a tube 21 bent essentially in an L-shape comprising an essentially horizontal tube section 22 which, as shown in Fig. 3, is attached, in known manner, in a pivoting manner relative to the rail section 5, and an essentially

vertical tube section 23 on which the claw grip 17 is mounted. The figures also show the jaws 18 and 19. The jaw 18 consists of a first clamping part 24 and a mounting part 25 consisting of a sleeve 26 mounted on the tube section 23. In the embodiment shown, the sleeve 26 is mounted on the tube section 23 with a drive fit, ensuring that the jaw 18 is attached securely to the arm 16.

The mounting of the sleeve 26 on the tube section 23 may obviously take any of the forms known to one skilled in the art for achieving a secure connection between the parts. The jaw 19 consists of a second clamping part 27 and a shaft section 28, which is movably mounted in the tube section 23. An elastic element in the form of a coil spring 29 acts with a first end 30 on the shaft section 28 and rests with a second end 31 on a support 32 located in the tube section 23, whereby the jaw 19 is pressed apart from the jaw 18 by the force of the coil spring to open the claw grip 17. The shaft section 28 is provided with an attachment ring 33 to which a cable 34 is connected and which cable runs through the L-shaped tube to an attachment to a tightening device 35 mounted on the L-shaped tube 21. Operation of the tightening device causes the cable 34 to pull the jaw 19 downward towards the jaw 18 against the force of the coil spring 29.

The tightening device 35 is shown in detail in Fig. 7, in which certain parts are cut away to show the operation of the device more clearly. Since the operation of the device as part of the invention can be achieved in a large number of ways, only a general description with reference to Figs. 5 and 7 will be given. The device incorporates a body part 37 which, at the lower end 38, is attached to the horizontal tube section 22 of the retaining arm 16. In the upper end 39 of the body part is a drum 40 journalled in bearings which, by means of a handle 41, can be rotated clockwise as indicated by the arrow U.

The drum 40 is provided with a saw tooth periphery 42 which engages with a saw tooth pawl 43, which pawl is spring-loaded in the direction towards the saw tooth periphery 42, which spring is not shown in the figures. The cable 34 is attached to the drum 40 and is wound onto the drum 40 when the drum is rotated clockwise, causing the movable jaw 19 to move towards the fixed jaw 18 and preventing the coil spring 29 from moving the jaw 19 apart from the jaw 18 due to the interaction between the saw tooth periphery 42 and the pawl 43. The pawl 43 is in contact with and is acted on by an operating button 44, with which the pawl 43 can be made to disengage from the periphery, enabling the drum 40 to be rotated counter clockwise and the coil spring 29 to

press the jaw 19 apart from the jaw 18 to a position in which the claw grip is opened Fig. 6 is a detail view of a securing device 6 through section D-D in Fig. 3.

The figure shows the longitudinal rail section 5. The securing device incorporates a cradle 45 mounted on the rail section 5, which cradle is U- shaped in cross-section, with a high flange 46 and a low flange 47. The cradle 45 is provided with a tightening strap 48 on the same side as the high flange and a snap catch 49 on the same side as the low flange 47. The wheels of a loaded bicycle are secured to the securing devices by passing the tightening strap 48 through the wheel and securing it with the snap catch 49.

The function and use of the load carrier will be described below with reference to Figs. 1-7. When a bicycle is to be loaded onto a load carrier mounted on a vehicle roof, the bicycle is loaded from the side indicated by the arrow S in Fig. 3 and the retaining arm 16 is turned to the position shown in Fig. 3. Since the friction of the retaining arm attachment is such that that the arm remains in the position to which it is adjusted, and when the claw grip is adjusted to the open position by the coil spring 27, causing the jaws to form a gap 50 facing the direction of loading, the user is not required, once the arm has been moved into position, to pay further attention to the arm or claw grip until the claw grip is to be tightened. The bicycle is then lifted onto the rail section 5 from the direction indicated by the arrow S in Fig. 3 and placed with each wheel in its respective securing device 6. Since the high flange 46 of the securing device is located at the side of the rail section furthest from the direction of loading, the possibility of the wheel passing beyond the rail and being placed on the vehicle roof is largely eliminated. When the bicycle has been loaded and raised into the upright position, as shown in Fig. 1, a section of the bicycle frame 51 will be seated in the claw grip 17, which is in the open position. Since the front wheel of the bicycle is resting on area 10 of the rail section and the rear wheel is resting on area 9, the bicycle will tend to move in the direction of the arrow F, causing the frame 51 to come into active contact with the jaw 18 and, specifically, with the recess 20, whereby the bicycle is afforded such support that it remains upright without any other support. The claw grip is then tightened by rotating the drum 40 clockwise with the handle 41 and the straps 47 are thereafter used to secure the wheels to the rail section.

To ensure that the bicycle is given sufficient momentum to move, the angle a should suitably be between 179 and 160 degrees, and an advantageous angle

has been shown to be between 175 and 165 degrees, and the most advantageous angle is one between 174 and 172 degrees. The recess 20 provides enhanced safety against the risk that the bicycle will fall before the claw grip is tightened, although it will be clear to one skilled in the art that the load carrier will function satisfactorily even if no recess is provided.

In the figures, the frame 51 is shown in contact with the jaw 18 ; however, it will be clear to one skilled in the art that if the area 10 were angled in the opposite direction, the frame 51 would come in contact with the jaw 19, in which case the jaw 19 should be fixed and the jaw 18 movable.