SE524508C2 - Hose tower for fuel pump device - Google Patents

Abstract

A column for a fuel pump unit, comprising at least a hose storage space (6) in the column, a hose (5) whose one end is fixed in the hose storage space (6), an opening of the hose storage space (6), through which opening it is possible to pull out the hose (5), and a hose returning means which is adapted to return the hose (5) to the hose storage space (6). The hose returning means comprises a movable control means (11; 20), through which the hose (5) runs, said control means (11; 20) applying on the hose (5) a force acting towards the hose storage space (6). The control means (11; 20) is adapted to provide support to the hose essentially along the entire circumference of the hose. <IMAGE>

Description

lO 15 20 25 30 35 p ø - u. o. placed facing the fuel pump. It is not always known to a driver of an unfamiliar vehicle if the fuel filler flap is on the left or right side. This can lead to the driver accidentally parking the vehicle on the wrong side of the pump, and thus can not refuel without moving the vehicle to the other side of the petrol pump, as the hose does not reach around the car.

One way to simplify access to the petrol pump is to provide it with a longer hose. However, this can cause problems because a longer hose can have a tendency to end up on the ground when not in use and thus get stuck in or damaged by passing cars or other vehicles.

To avoid this, the hose tower may be provided with some form of return mechanism for the hose.

A fuel pump with a return mechanism for the hose is described in Australian patent 505071. arranged flexible spring which is arranged vertically from In said patent the hose is fixed in a vertical upper side of the fuel pump. The hose runs from the fuel pump up to the bracket in the vertically arranged flexible spring and then runs to the nozzle with which you refuel. With such a return mechanism, the hose ends up on the ground. However, the extra hose length that can be used is limited to the spring deflection. In addition, there is the risk that something may get stuck in the hose that hangs from the fuel pump up to the bracket in the spring. It is also difficult to arrange several hoses close to each other because it gets messy. It is therefore nowadays most common to arrange the hose in a hose tower in which the hose can be stored when not in use.

A fuel pump with automatic return of the hose to the hose tower is described in EP-A1-0 379 742. In this known construction, the hose runs inside the hose tower around a number of fixed smaller rollers and around a wheel loaded with verti spring. bare direction movable, The hose is attached to the ceiling of the hose tower at the rear side and 10 15 20 25 30 35 524 508 ~. I - .u ~ u «| n ø,,, _ _. 3 is guided along the back down around the wheel. From the wheel, the hose is led further up at the front to the rollers, and further over the rollers to the back of the tower. The hose hangs freely downwards from the rollers and has thus been guided around a turn in the tower.

The spring load causes the hose to be pulled back into the hose housing after use, but also acts as a restraint when pulled out. The restraining effect has the disadvantage that it becomes difficult to pull out the hose, and it is therefore common for a driver not to take advantage of the advantages a longer hose offers in terms of being able to park the vehicle further from or on any side of the petrol pump. If the spring load is reduced in order to reduce the restraining force, the hose is not inserted as efficiently, and risks remaining outside the hose tower after use.

Another example of such a construction is shown in EP-B1-0 0 255 979, which, however, also suffers from the above-mentioned problems with regard to return action and restraining force.

Another example of a similar construction is shown in NL-A-8 403 718. As can be seen from the drawings in this document, the construction comprises a vertically displaceable, spring-loaded wheel and a fixedly mounted wheel around which wheels the hose runs inside hose tower. The hose is attached to the ceiling of the hose tower and is led out - with the back of the hose tower down around the movable wheel. From there, the hose is led up along the front to the fixed wheel, and then further over the fixed wheel to the back of the tower. The hose hangs freely downwards from the permanently mounted wheel and has thus been guided around a turn in the tower. Like the above, this construction has corresponding problems with feedback effect and restraining force.

A further example of a feedback mechanism is shown in PCT application WO OO / 15542. A problem with this return mechanism is that the hose opens out near the ground 10 l5 20 25 30 35 524 508 u ~ n n u u n n | u | . -. .. 4 which results in the hose easily dragging in the ground.

In addition, it is sluggish to pull out such a hose at the same time as the available hose length is small in relation to the volume of the hose storage space.

A problem with all the described hose return mechanisms in which the hose is rolled in in some way is that the hose can be difficult to pull out at certain angles in relation to the fuel pump. This means that you have to pull out and insert the hose at a certain angle in relation to the fuel pump. Another problem is that they are relatively complicated and thus costly.

Thus, there is a need for a device that allows in and discharge of the hose substantially independent of the angle of the hose relative to the hose tower.

SUMMARY OF THE INVENTION An object of the present invention is to provide a hose tower intended for a fuel pump assembly, which hose tower has a hose return mechanism which is inexpensive and which allows sufficient elongation of the part of the hose which is outside the hose tower when the hose is pulled out.

A further object of the present invention is to provide a hose tower with a hose return mechanism which allows discharge and retraction of the hose substantially independent of the angle relative to the hose tower.

Another object of the present invention is to provide an uncomplicated and inexpensive hose tower with hose return mechanism. The present invention aims to fulfill at least one of these objects. At least one of these objects is fulfilled with a hose tower according to the invention which has the features stated in the independent patent claim. Preferred embodiments are set out in the appended dependent claims. A hose tower for a fuel pump device, according to the invention comprises at least one hose storage space in the hose tower, a hose one end of which is fixed inside the hose storage space, an opening into the hose tower. the hose storage space through which opening it is possible to pull out the hose, and a hose return means which is arranged to return the hose to the hose storage space. A hose tower according to the invention is characterized in that the hose return means comprises a movable guide means through which the hose runs, which guide means acts on the hose with a force towards the hose storage space and which guide means is arranged to enable support for the hose substantially around the entire circumference of the hose.

Such a hose tower allows easy hose handling while being relatively uncomplicated to manufacture.

When a user pulls the hose out of such a hose tower, the hose will be straightened and thereby give the user better range from the hose tower. By the hose running through the guide member, which is arranged to enable support of the hose mainly around the entire circumference of the hose, it becomes possible to pull out the hose at, at virtually any angle, in relation to the axis of symmetry of the hose at the guide member.

There are several ways of arranging a suitable guide means according to the invention.

In a hose tower according to an embodiment of the invention, the guide means is rotatable at least about an axis of rotation which is substantially perpendicular to the longitudinal axis of the hose. This enables the guide member to be rotated relative to the hose tower when the direction in which the hose is pulled out changes.

In some cases it is desirable to have a sequentially acting hose return means. In such a hose tower, it is desirable that the path of the hose outside the hose storage space can be extended further in addition to the shortening achieved by straightening the hose. According to an embodiment of the invention, the hose return means also comprises an arm which in a first end is rotatably arranged in the hose storage space, the guide means being rotatably suspended in the other end of the arm and wherein a spring element is arranged to actuate the guide means and the arm towards the hose storage space. In such a hose tower, it is relatively easy to arrange a break wheel over which the hose can be run.

According to an embodiment of the invention, the hose is therefore arranged to run over at least a first breaking wheel which is suspended in the hose storage space.

It is then possible to easily arrange the hose tower so that the hose runs in a loop of variable length.

It is advantageous to arrange the wheel in the same axis of rotation as the first end of the arm, since then you do not need several axes of rotation. This makes the hose tower easier and less expensive to manufacture.

According to an embodiment of the present invention, the hose return means also comprises a spring element which at one end is attached to the guide means and at its other end is guided in a guide point in the wall of the hose storage space which is opposite the opening to the hose storage space. The spring element acts on the guide member in the direction of the guide point.

By pulling the guide member towards the guide point with a spring element, it is possible to make the guide member rotatable about all possible axes of rotation.

According to an embodiment of the invention, the hose storage space is limited by two side walls, a floor, a roof, a front wall in which the opening is located and a rear wall opposite the front wall. The hose is attached to the ceiling closer to the opening in the front wall than the rear wall.

By having the attachment point closer to the opening than the rear wall, it becomes relatively easy to shorten the reach of the hose simply by pulling the hose into a u-uq-n 10 15 20 25 30 35 n u u »u. ,, ,,. n q. : n u v o n u. o u u fo f. u u u n n n n n n. , :now ,, , , . '. I I n a »e. . ,, z g ° u o n v n ..- e - <v u o ~ - ». ,. 7 loop running backwards towards the rear wall in the hose storage space.

By arranging the guide point in the rear wall according to an embodiment of the invention, maximum shortening of the loop is obtained.

According to one embodiment, the spring element is fastened in a fastening point which coincides with the guide point.

However, if the spring element is fixed at a fixed point at a distance from the guide point, the advantage is obtained that the guide member is allowed to be moved a longer distance than in the previous case, when the same force is applied to the guide member. By having the guide point and the attachment point separated, it is thus possible to vary the length of the spring element without varying the distance between the guide point and the guide member.

According to an embodiment of the invention, the guide means consists of a ring or sleeve. It is relatively simple and straightforward to make a ring or sleeve while it is sufficient to guide the hose in all directions. The axial length of the ring or sleeve can be varied optionally.

It is of course desirable that the friction between the ring and the hose is low, which is achieved, for example, if the ring is made of plastic. Examples of useful patches are (PTFE), possible to make the ring in any other material such as Teflon nylon and polyethylene. It is of course that low friction is obtained between the ring and the hose.

According to an alternative embodiment, the guide means consists of a plurality of wheels on which the hose is guided as it runs through the guide means independent of the angular direction of the hose in relation to the longitudinal axis of the hose at the guide means. This is a much more complicated solution but has the advantage that the friction between hose and guide means can be made lower.

According to an embodiment of the present invention, there is provided a hose return means in addition to the control means, which hose return means acts sequentially with the control means. For example, the second break wheel is arranged so that it is spring-loaded.

Of course, the above features can be combined in the same embodiment.

The invention will be described in more detail in the following with reference to the accompanying schematic drawings which, by way of example, show embodiments of the invention. The same reference numerals have been used for similar components in the various drawings.

Brief Description of the Drawings Fig. 1 shows a fuel pump assembly straight from the front.

Fig. 2 shows the inside measurement of a hose storage space from the side according to an embodiment of the invention.

Fig. 3 and Fig. 4 correspond to Fig. 2, but show other positions of the hose.

Figs. 5 and 6 show in a corresponding manner the inside measurement in the hose storage space for another embodiment of the invention. Fig. 7 shows in cross section a control member according to an alternative embodiment of the invention.

Detailed Description of the Preferred Embodiment As shown in Fig. 1, the fuel pump assembly comprises as main components a hose tower 1, a pump housing 2 and a display unit 3. The fuel pump assembly is connected to an underground fuel tank (not shown). When refueling a vehicle, the fuel is pumped from the underground tank by means of a pump P located in the pump housing 2, and further from there to the hose tower 1 and out to a refueling nozzle 4 (gun valve) via a hose in the form of a fuel hose 5 When refueling does not take place, the fuel hose 5 is inserted into a hose storage space 6 and the refueling nozzle 4 is suspended in a fork 7.

As can be seen from Fig. 2, the fuel hose 5 is connected to the fuel pump assembly of the fuel pump assembly at the upper and relative to the user rear portion of the hose storage space 6. The fuel hose 5 runs from a first breaker wheel to the fork 7 after the fuel hose 5 11-0 5 24 508 "9 is first led downwards around a second break wheel 8, which is located at the lower, and in relation to the user rear, the portion of the hose storage space 6. From the second break wheel 8 the fuel hose 5 is led upwards in the hose storage space 6 and is supported by the first breaker wheel 9, which is located in the upper and relative to the user front portion of the hose storage space 6. From the first breaker wheel 9 the fuel hose 5 hangs downwards in a bend and folds upwards again, since one is arranged at the end of the fuel hose 5 refueling nozzle 4 is suspended in the fork 7 which is located approximately in the middle of the hose tower 1 in height and on it in relation to the front side of the user n of the hose tower 1. An arm 10 is at a first end rotatable about an axis common to the first breaking wheel 9. At the other end of the arm, a guide means in the form of a sleeve 11, through which the hose 5 can run, is rotatably arranged around an axis of rotation 12. The arm 10 is spring-loaded with a spring element 13, which acts on the arm which in turn acts on the sleeve 11 and the hose 5 towards the storage space 6. The second break wheel 8 is spring-loaded and arranged to be able to move in the vertical direction when pulling out and returning the fuel hose 5. The movement and function of these two components will be described in more detail in the following.

When a user intends to use the fuel pump unit, he lifts the refueling nozzle 4 from the fork 7 and pulls the fuel hose 5 outwards. In this action, the sleeve 11 will be rotated about its axis 12 towards the user, since the fuel hose 5 will abut against the first breaker wheel 9 and pull the sleeve 11 outwards. The hose length obtained in this maneuver is the length which was located in the downward loop from the first breaker wheel 9 to the refueling nozzle 4.

For returning the hose 5, the arm 10 is, as mentioned above, provided with a spring 13 which is arranged to return the arm 10, and the sleeve 11 mounted thereon and thus the hose 5 to its original position (see Fig. 2) after. . : o u. lO 15 20 25 30 35 524 508 særæa: - = § "_. '.,: 1: 3' xz; ~ u -». u 10 use. The spring 13 is a tension spring which is attached with one end in an attachment point 14 in the interior of the hose storage space 6 and with the other end in an attachment point 15 located on the arm 10 between the sleeve 11 and the common axis of rotation of the first breaker wheel 9 and the arm 10. When the arm 10 is rotated, it perpendicular the distance between the axis of rotation 12 and the force line of the spring 13, ie the torque lever, to be shortened.The spring 13 stores the energy required to pull out the hose 5 in the form of potential energy.By appropriate selection of the mutual positions of the attachment points 14 and 15 in In relation to the rotary shaft 12 together with the choice of spring constant for the spring 13, solutions can be provided where the hose return force is optimized with respect to the return of the hose 5 and the required pull-out force is optimized with respect to user-friendliness. have the least favorable working position ensure that the counteracting force from the return spring 13 is as small as possible, while one can ensure that the return force is as large as possible at the last part of the return movement to ensure that the hose 5 is returned into the hose storage space 6.

When the hose 5 is pulled out to the position shown in Fig. 3, further extension of the hose 5 will cause the wheel 8 to move substantially vertically upwards as shown in Fig. 4. In this vertical movement of the wheel 8, additional hose length is obtained which can be used to pull the hose to a slightly misplaced vehicle or around a vehicle to the other side for access to the vehicle's tank connection. The wheel 8 is connected to a spring 16 which is pulled out when the hose 5 is pulled out. The spring 16 which is a tension spring is connected at one end in an attachment point 17 which accompanies the wheel 8 and at the other end in an attachment point 18 which is fixed in relation to the hose storage space 6. The spring 16 stores the work required to pull out the hose 5 in the form of potential 1 | - - v; .w- lO 15 20 25 30 35 524 508; ¿@ «. =« zfwf »~ ^ -e == -.- '- v. - - a ll energy. Since the vertical movement of the wheel 8 in cooperation with the movement of the arm 10 straightens the hose 5, a large hose length is obtained in relation to the work required to pull it out.

The method in which the fuel pump unit is intended to be used will be described in the following. The driver who intends to refuel his vehicle drives up to the side of the fuel pump unit. The driver then selects the fuel location and lifts the refueling nozzle 4 from the fork 7.

When pulling out the hose 5, the arm 10 will first be turned towards the user. During this rotational movement, the spring 13 will store the work required in the form of potential energy. If the refueling nozzle 4 reaches the refueling connection of the vehicle, refueling is started. If the vehicle is positioned so that the refueling nozzle 4 does not reach the refueling connection of the vehicle, the driver will pull further in the hose 5, which has the consequence that the arm 10 may be rotated a little further, but above all the wheel 8 will be moved vertically upwards. Here, too, the spring 16 will store the work required in the form of potential energy. When refueling is complete, the driver will release the refueling nozzle 4 from the refueling connection of the vehicle and release as first the spring 16 of the wheel 8 and then the spring 13 of the arm 10 return the hose 5 to the hose storage space 6. Thanks to this sequential action between the arm 10 and the wheel 8 pulling out and returning the hose 5, you can optimize the return function at the same time as you can make the design very user-friendly.

Figures 5 and 6 show another embodiment of the present invention. The embodiment shown in Fig. 5 and Fig. 6 is simpler and cheaper than the first described embodiment. As shown in Fig. 5, the fuel hose 5 is connected to the fuel pump assembly of the fuel pump assembly at the upper and relative to the user front portion of the hose storage space 6. The hose 5 is guided downwardly by a guide means 20 which is a hollow shaft 20. connected to a spring element 21 which runs via a guide point 22, which is arranged on the rear wall of the hose storage space, up to an attachment point 23. After the sleeve 20, the hose runs in a loop downwards and further up to a refueling arranged at the end of the hose ~ nozzle 4 which is suspended in the fork 7 on the front of the hose tower. The spring element 21 acts with a spring force on the sleeve 20 in the direction of the guide point 22. By the spring element 21 running from the guide point 22 further towards a fastening point 23 at a distance from the guide point 22, the spring force can be varied by varying said distance in addition to changing the spring constant of the spring element 21. .

When a user is to refuel his car with the refueling nozzle 4, he lifts it from the fork 7 and pulls on the hose 5. When the user pulls out the hose, the spring element 21 will be stretched at the same time as the hose 5 runs through the sleeve 20 so that the sleeve 20 comes closer to the hose 5 attachment to the ceiling. By allowing the hose 5 to run through the sleeve 20, the total length of hose allowed outside the hose tower will be available at a much lesser force than it would have been if the hose were directly attached to the spring member because the point in the hose where the spring member 21 is attached would then need is moved a longer distance than the sleeve 20 needs to be moved in a hose tower according to the invention.

The force acting on the hose can be varied in one or more of the following ways. The length of the spring element can be varied, its spring constant can be selected, the position of the guide point can be varied and the distance between the guide point 22 and the attachment point 23 can be varied. A person skilled in the art can easily arrive at the right parameters through a few simple experiments as the invention has now been presented.

The sleeve 20 is according to an embodiment made of plastic, but of course it is possible that it is of some other material, such as for instance some metal. The essential 10 15 20 25 30 35 524 508: j fi jïf "13 is that the friction between the hose 5 and the sleeve 20 is sufficiently low so that the hose 5 runs easily through the sleeve 20.

For example, the sleeve 20 is made of Teflon, nylon, polyethylene, brass or steel but can also be of any other material. A person skilled in the art will find any suitable material in the light of the description of the invention above.

It will be appreciated that a variety of modifications of the embodiment described herein are possible within the scope of the invention, which is defined in the appended claims.

For example, the suspension of the sleeve in an arm according to Figs. 1-4 can be combined with the hose running only through the sleeve, according to the embodiment in Figs. 5 and 6, without going through any breaking wheel.

Correspondingly, the suspension of the sleeve in a spring element according to the embodiment in Figs. 5 and 6 can be combined with having two breaking wheels according to the embodiment in Figs. 2-4, for sequential extension of the hose.

Furthermore, for example, the tension springs can be replaced by any other spring or other element with a corresponding function, such as, for example, some form of coil spring-loaded rope reel, rubber band or the like. The springs can also be replaced with a weight. A weight is usually somewhat more space-consuming, but in return gives the same counteracting load during the entire extraction of the hose.

According to an alternative embodiment, one and the same spring is used for returning both the arm and the first breaking wheel. In this case, the sequential action can be achieved, for example, by coupling the arm and the wheel to the spring at different lengths of the spring.

The arm may, for example, be attached to one end of the spring, while the wheel is attached to the spring by means of a hook arranged on the spring which engages with the wheel after the spring has been extended a certain length. ~ | ea nu -v- 524 sus; ߧ¿;: rß «ä: = *" '' 'I = 0 - o ~. «... ~ fl. l4 The hose storage space can be a more or less open space instead of the The important thing is that the hose is returned to a place where it is not accessible to passing vehicles or the like.

The sleeve can be replaced with any other construction such as a plurality of support wheels as shown in figure 7. Figure 7 shows in cross section how the hose 5 runs through the guide member with a plurality of support wheels 24.

Claims (11)

10 15 20 25 30 35 524 508 15 PATENT REQUIREMENTS A hose tower for a fuel pump device, the hose tower comprising at least one hose storage space (6) in the hose tower, a hose (5) substantially vertically suspended inside the hose storage space, one end of which is fixed inside (6), an opening into the hose storage space (6) the hose storage space through which opening it is possible to pull out the hose (5), and a hose return means arranged to return (6), which hose return means comprises a movable guide means for guiding the hose (5) to the hose storage space (11; 20) through which the hose ( 5) runs, which guide means (11; 20) acts on the hose (5) with a force towards the hose storage space (6) and which guide means (11; 20) is arranged to enable support for the hose substantially around the entire circumference of the hose, the hose return means ( 10) arranged just in the hose storage space (13) and the arm towards the hose storage space which at a first end is rotatable (6), is arranged to influence the guide- also comprises an ar m and wherein a spring element means the means (11, 20) (6) characterized in that the hose is arranged to run over at least a first breaking wheel (9) which (6) is rotatably suspended in the arm is suspended in the hose storage space and in that ( ll; 20) (10) other end about an axis of rotation which is substantially the guide means perpendicular to the longitudinal axis of the hose. Hose tower according to claim 1, wherein the first break wheel (9) is suspended in the same axis of rotation as the first end of the arm (10). A hose tower according to claim 1 or 2, wherein the hose return means also comprises a spring element (13) which is attached at one end to the guide means (11; 20) and at its other end is guided in a guide point (22) in the wall of the hose storage space (6) which is opposite the opening to the hose storage space, the spring element actuating the guide means (11; 20) in the direction of the guide point. A hose tower according to claim 3, wherein the hose storage space is limited by two side walls (30), a floor (31), a roof (32), a front wall (33) in which the opening is located and a rear wall (34) opposite the the front wall (33) and wherein the hose (5) is attached to the ceiling (32) closer to the opening than the rear wall. A hose tower according to claim 4, wherein the guide point is arranged in the rear wall (34). 4 or 5, wherein (23) The hose tower according to claim 3, (21) coincides with the guide point is fixed in an attachment point which (22). Hose tower according to claim 3, (21) distance from the guide point. the spring element 4 or 5, the spring element being fixed in a fastening point (23) on Hose tower according to one of the preceding claims, (11; 20) A hose tower according to claim 5, wherein the ring is wherein the guide means is constituted by a ring. of plastic. A hose tower according to any one of claims 1-7, wherein the guide means (35) consists of a plurality of wheels (24) on which the hose (5) is guided as it passes through the guide means independent of the angular direction of the hose in relation (35). 11. ll. Hose tower according to one of the preceding claims, to the longitudinal axis of the hose at the guide means, wherein a second hose return means (16, 17, sequentially with the guide means. 18) is provided, which hose return means acts