AN ANTI-SLOSHING MECHANISM

The present invention relates to an anti-sloshing mechanism provided in motor vehicles.

If a liquid is provided in a tank or a similar chamber subject to movement, such a liquid tends to move according to the movement of the tank. Each time the acceleration affects the tank, the liquid in the tank creates agitation when it hits the walls of the tank. Motion dynamics can vary in vehicles and can create large accelerations. Internal and external fuel tanks are the most important tanks in use. These chambers can contain a large amount of liquid fuel due to their mission needs, and can be used wherever required. Depending on power and dimensions of the vehicle, the liquid agitation in the tank with the effect of the acceleration due to the dynamic movement can create a force sufficient to affect the dynamics of the vehicles, depending on the volume of the liquid. This can create undesirable and dangerous displacement effects in the general and local center of gravity. In order to prevent agitation and effects thereof, anti-sloshing units are used in various geometries and numbers in the tank or chamber.

US6736282B2, which is included in the known-state of the art, discloses a slosh-inhibiting element for the fuel in a fuel tank. It discloses a latching mechanism which allows for fixation of the anti-sloshing element to the inner wall of the fuel tank. The slosh-inhibiting element has a mounting position in which the fuel tank can be inserted through a mounting opening. It is produced separately from the fuel tank and can be installed via the mounting opening.

Thanks to an anti-sloshing mechanism according to the present invention, anti-sloshing mechanisms that are in detachable form to fuel tanks are provided.

An object of the present invention is to provide an anti-sloshing mechanism in a geometrical structure that can prevent the sloshing and/or agitating movement of the liquid in fuel tanks. Another object of the present invention is to provide a locking mechanism that can fix the sloshing mechanism at a desired position in the fuel tank.

A further object of the present invention is to provide an anti-sloshing mechanism that can be received and mounted to the fuel tank after the production of the fuel tank.

The anti-sloshing mechanism realized to achieve the object of the invention, which is illustrated in the first claim and other claims dependent thereon, comprises a tank provided in a motor vehicle for containing a fuel. There is at least one anti-sloshing member in the tank, at a position predetermined by the user. Depending on the movement of the motor vehicle, the fuel in the tank can undesirably slosh, agitate and accelerate. In motor vehicles, anti-sloshing members are used to prevent unwanted acceleration and agitation of the fuel in tanks which carry the fuel while the vehicle is in motion.

The anti-sloshing mechanism according to the invention comprises a plurality of blades forming the anti-sloshing member in the same form as the section of the tank. Each of the blades is mounted in the center to form the anti-sloshing member. There is a locking element that fixes the anti-sloshing member in the tank so that it touches both the center and the inner wall of the tank. The anti-sloshing member is formed by connecting/mounting the blades to each other. The anti-sloshing member, which consists of N-blades, is received into the tank by the user. The anti-sloshing member is preferably mounted on the tank in a removable way, in case it is needed. The blades are preferably fan-shaped in fuel tanks. The center is preferably in the form of a joint. There is a locking element that locks the anti-sloshing member in the tank such that it contacts both the center and the inner wall of the tank.

In an embodiment of the invention, the anti-sloshing mechanism comprises a plurality of channels located on the center to surround the center. The blades are moved radially around the center on the channels and are brought to positions predetermined by the user. The center is preferably in the form of a joint, on which channels are provided. N- blades move radially in N-channels. The blades are opened by sliding over the channels in the tank and anti-sloshing is provided. In an embodiment of the invention, the anti-sloshing mechanism comprises at least one access door providing access to the anti-sloshing member and allowing the anti-sloshing member to be brought to a position predetermined by the user. There is a closed position (I) in which each of the blades is positioned on the center facing each other so that they can be inserted by the user through the access door; and an open position in which the blades are triggered by the user around the center and touch the inner wall of the tank to wrap the inner wall of the tank (II). The blades are received into the tank piece by piece through the access door. Each of the blades is overlapped and is in a closed position (I), which appears as a single blade when viewed from the front. The blades, which have been received into the tank through the access door by the user, are moved around the center on the channels so as to rotate around the center and open. There is an open position (II) in which the blades are open and take the form of the inner wall of the tank by contacting thereto, thus creating the anti-sloshing form.

In an embodiment of the invention, the anti-sloshing mechanism comprises a plurality of slots on each blade. There is a plurality of pins on the locking element, which are formcompatible with the slots and are inserted into the slots. When the pins are inserted into the slots, the anti-sloshing member is fixed in the position predetermined by the user. When the anti-sloshing member is opened in the tank and brought to the desired position, a locking element is used to fix the anti-sloshing member.

In an embodiment of the invention, the anti-sloshing mechanism comprises a plurality of first pins on the locking element. Primarily, the first pins contact with the slot. Thus, it allows the anti-sloshing member to be kept in the position where it is desired to be fixed in the tank. There is a plurality of second pins on the locking element that are secondarily inserted into the slots. The second pins trigger the blades, allowing the blade tips to contact the inner wall of the tank and locking the anti-sloshing member inside the tank. The first pins enable the anti-sloshing member to remain in the desired position in the tank, and the second pins provide the main locking and fixation the anti-sloshing member. When the blades are opened on the joint, the first and second pins are inserted into the slots provided on the blades.

In an embodiment of the invention, the anti-sloshing mechanism comprises a plurality of first slots on the blades, which are eccentric in shape. The first slots are form-compatible with the first pins and the first pins are inserted into the first slots. By inserting the first pins into the first slots, the blades forming the anti-sloshing member in the tank are fixed in the position predetermined by the user. After the first pins and the first slots are positioned opposite each other in the tank and the first pins are inserted into the first slots, the second pins on the locking element are inserted into the second slots on the blades. Thus, locking is provided and the anti-sloshing member is fixed in the position determined by the user in the tank. The first pins are moved towards the first slots by the user. The first pins are inserted in the first slots. In order for the anti-sloshing member to remain fixed in the desired position in the tank, the second pins are placed in the second slots. Thus, the antisloshing member is locked in its position in the tank. During the locking of the antisloshing member, the blade tips are pressed against the inner wall of the tank.

In an embodiment of the invention, the anti-sloshing mechanism comprises the locking element made of a harder material than the anti-sloshing member. Thus, when the pins are positioned in the slot in an opposite manner, the locking element pushes the blades to the inner wall of the tank and presses the blade tips to the inner wall of the tank to fix the anti-sloshing member. When the locking element is preferably made of a harder material than the anti-sloshing member, the pins are made of harder material than the blades, and when they meet the slots, they push the slots. In this way, the blades are pushed towards the inner wall of the tank and the anti-sloshing member is locked.

In an embodiment of the invention, the anti-sloshing mechanism comprises the antisloshing member consisting of a plurality of blades in L and/or T flange form, which are received individually or integrally into the tank through the access door. The blades contact the inner wall of the tank at the flange parts and surround the inner walls of the tank by the locking element. There are blades in L or T flange form. Flange-shaped blades are received into the tank by the user individually or in an assembled manner through the access door. While creating the anti-sloshing structure by means of the blades, in this embodiment, the blades, which are piece by piece, are mounted directly to each other to form the anti-sloshing member, preferably without a radial sliding movement. The blades are mounted individually on the center so as to almost completely surround the inner surface of the tank. The flanged anti-sloshing member is fixed in the desired position in the tank by the locking element. In an embodiment of the invention, the anti-sloshing mechanism comprises a plurality of gaps on each blade. There is a plurality of protrusions on the locking element that are form-compatible with the gaps. The protrusions are opposite the gaps and inserted into the gaps. L and/or T shaped flanged blades are received into the tank individually, and the blades are mounted without a slide-opening movement. Blades are mounted in the tank or received into the tank after assembly. In this embodiment, the locking element comprises protrusions that are engaged into the gaps in the blades. Therefore, the protrusions are inserted into the gaps and the anti-sloshing member is locked in the position determined by the user in tank.

In an embodiment of the invention, the anti-sloshing mechanism comprises a plurality of holes which are provided on the blades in geometric shapes predetermined by the user. Thanks to the holes, the fuel will be almost completely prevented from sloshing and/or agitating in the tank. The holes also allow the fuel to be directed along the tank between the blades and/or the anti-sloshing members in case of multiple anti-sloshing members, in a manner predetermined by the user.

In an embodiment of the invention, the anti-sloshing mechanism comprises the fuel tank provided in air, space, land and/or sea vehicles.

The anti-sloshing mechanism realized to achieve the object of the invention is illustrated in the attached drawings, in which:

Figure 1 is a perspective view of the anti-sloshing mechanism and the tank.

Figure 2 is a front view of the anti-sloshing member in the closed position (I).

Figure 3 is a front view of the anti-sloshing member in the open position (II).

Figure 4 is a perspective view of the anti-sloshing member in the open position (II).

Figure 5 is a perspective view of the locking element.

Figure 6 is a front view of the blade, first slot and second slot.

Figure 7 is a perspective view of the blade in the form of a T flange.

Figure 8 is a perspective view of the anti-sloshing member consisting of blades in the form of T flanges.

Figure 9 is a schematic view of the locking element when the protrusion is inserted into the gap. All the parts illustrated in figures are individually assigned a reference numeral and the corresponding terms of these numbers are listed below:

1. Anti-sloshing mechanism

2. Anti-sloshing member

3. Blade

4. Center

5. Locking Element

6. Channel

7. Access door

8. Slot

801 - First slot

802 - Second slot

9. Pin

901 - First pin

902 - Second pin

10. Gap

11. Protrusion

12. Hole

(T) Tank

The anti-sloshing mechanism (1) comprises a tank (T) located in a motor vehicle for containing fuel; at least one anti-sloshing member (2) located in the tank (T) at a position predetermined by the user and preventing the fuel from sloshing and/or agitating in the tank (T) at a rate predetermined by the user (Figure 1).

The anti-sloshing mechanism (1) according to the invention comprises a plurality of blades (3) located in the anti-sloshing member (2) in a form-compatible manner with the section of tank (T); a center (4) to which each of the blades (3) is mounted to form the antisloshing member (2); a locking element (5) that fixes the anti-sloshing member (2) in the tank (T) such that the anti-sloshing member (2) almost completely contacts both the center (4) and the inner wall of the tank (T). The anti-sloshing mechanism (1) is used in tanks (T) of motor vehicles that contains fuel, in order to prevent undesired acceleration and agitation of the fuel and to ensure that the fuel is directed as desired by the user. At least one anti-sloshing member (2) is provided in the tank (T) at a position predetermined by the user.

There is a plurality of blades (3) forming the anti-sloshing member (2) so as to be formcompatible with the section of the tank (T). The anti-sloshing member (2), consisting of N- blades (3), is received into the tank (T) by the user. The blades (3) are preferably fanshaped in cylindrical fuel tanks (T). The blades (3) are assembled around the center (4) to form the anti-sloshing member (2). The center (4) is preferably in the form of a joint. There is a locking element (5) that fixes the anti-sloshing member (2) in the tank (T) such that it touches both the center (4) and the inner wall of the tank (T). When the anti-sloshing member (2) is placed inside the tank (T), it is held rigidly by the locking element (5) (Figure 2, Figure 3, Figure 4).

In an embodiment of the invention, the anti-sloshing mechanism (1) comprises a plurality of channels (6) located on the center (4) to almost completely surround the center (4); the blades (3) which are moved radially on the channels (6) around the center (4) and brought to a position predetermined by the user. The center (4) is preferably in the form of a joint, on which channels (6) are provided. N- blades (3) make a radial sliding motion in N- channels (6). In this way, the blades (3) are opened in the tank (T) and form the antisloshing member (2).

In an embodiment of the invention, the anti-sloshing mechanism (1) comprises at least one access door (7) which allows the anti-sloshing member (2) to be brought to the position predetermined by the user, and provides access to the anti-sloshing member (2); the anti-sloshing member (2) which has a closed position (I) in which the blades (3) are positioned on the center (4) to face each other, thereby being received through the access door (7) by the user, and an open position (II) in which the blades (3) are triggered and opened by the user around the center (4), such that they almost completely take the form of the inner wall of the tank (T) and almost completely surround the inner wall of the tank (T). The blades (3) are received into the tank (T) through the access door (7). There is a closed position (I) in which the blades (3) are seen as a single blade (3) when viewed from the front, with each of the blades (3) facing each other. The blades (3) are preferably received into the tank (T) by the user in this closed position (I). The blades (3), which have been received into the tank (T) through the access door (7) by the user, are opened here. The blades (3) are rotated on the channels (6) around the center (4) so as to be opened. When the blades (3) are opened and take the form of the anti-sloshing member (2), they preferably take the form of a fan. There is an open position (II) in which, when all the blades (3) are opened, tips of the blades (3) contact the inner wall of the tank and thus the anti-sloshing member (2) is located to almost completely surround the inner wall of the tank.

In an embodiment of the invention, the anti-sloshing mechanism (1) comprises a plurality of slots (8) located on each blade (3); a plurality of pins (9) located on the locking element (5), which are form-compatible with the slots (8) and thus inserted into the slots (8) to fix the anti-sloshing member (2) in a position predetermined by the user. When the antisloshing member (2) is brought to the desired position in the tank (T) and the blades (3) are brought to the open position (II), the locking element (5) is used to keep the antisloshing member (2) rigid. There are slots (8) on each blade (3). Pins (9) are provided on the locking element (5), which are form-compatible with the slots (8) and prevent the antisloshing member (2) from moving when inserted into the slots (8).

In an embodiment of the invention, the anti-sloshing mechanism (1) comprises a plurality of first pins (901) located on the locking element (5), which make first contact with the slot (8), thus allowing the anti-sloshing member (2) to be kept in the position where it is desired to be fixed in the tank (T); a plurality of second pins (902) on the locking element (5), which are inserted into the slots (8) secondarily, thereby triggering the blades (3) so that the blade (3) tips almost completely contact the inner wall of the tank (T) and the antisloshing member (2) is almost completely fixed in the tank (T). The first pins (901) enable the anti-sloshing member (2) to be fixed in the open position (II) in the tank (T) and remain in the desired position. The second pins (902), on the other hand, push the blades (3) towards the inner wall of the tank (T) and press the tips of the blade (3) against the inner wall of the tank (T), thus providing locking and fixing.

In an embodiment of the invention, the anti-sloshing mechanism (1) comprises a plurality of first slots (801) on the blades (3) with an eccentric form, which are almost completely form-compatible with the first pins (901), wherein when the first pins (901) are positioned in the first slots (801), the first slots (801) allow the anti-sloshing member (2) to be brought to the desired position in the tank (T), in a position determined by the user; a plurality of second slots (802) on the blades (3), wherein after the first pins (901) and the first slots (801) are positioned facing each other in the tank (T), the second slots (802) are inserted into the second pins (902), thereby providing locking and fixing the anti-sloshing member

(2) in the tank (T) in a position determined by the user. When the first pins (901) are moved towards the first slots (801) by being triggered by the user, they push the blades

(3) to contact the inner wall, so that the anti-sloshing member (2) is at the desired position in the tank (T). When the first pins (901) are moved into the first slots (801), the second pins (902) fit into the second slots (802). Thus, the anti-sloshing member (2) is locked in its position in the tank (T). The blades (3) contact the inner wall of the tank (T) and are fixed until they are disassembled again by the user, so that the blades (3) remain immobile against possible sloshing and provide the anti-sloshing (2) feature (Figure 5, Figure 6).

In an embodiment of the invention, the anti-sloshing mechanism (1) comprises the locking element (5) made of a harder material than the anti-sloshing member (2), thereby pushing the blades (3) to the inner wall of the tank (T), pressing the blade (3) tips against the inner wall of the tank (T) and fixing the anti-sloshing member (2), when the pins (9) are positioned in the slot (8) to face each other. The locking element (5) is preferably made of a harder material than the anti-sloshing member (2). Therefore, when the locking element (5) is moved towards the anti-sloshing member (2), since the pins (9) are made of a harder material, when they meet the slots (8) they push the slots (8) to the inner surface of the tank (T). Thus, the blades (3) are pushed towards the inner wall of the tank (T) and the anti-sloshing member (2) is fixed.

In an embodiment of the invention, the anti-sloshing mechanism (1) comprises a plurality of blades (3) in L and/or T flange form, which are received individually or integrally through the access door (7) into the tank (T), which contact the inner wall of the tank (T) at the flange parts and which almost completely surround the inner walls of the tank by the locking element (5). A plurality of blades (3), which are in L and/or T flange form, are received into the tank (T) through the access door (7) individually or received into the antisloshing member (2) in an assembled manner. The blades (3) contact the inner wall of the tank (T) at their flange parts and surround the inner walls of the tank (T) by the locking element (5). Blades (3) are mounted individually to each other in the center (4) to form the anti-sloshing member (2). The blades (3) in the L-flange form are preferably received into the tank (T) in an assembled or disassembled manner, and the blades (3) are assembled without performing a rotating/sliding opening movement. Similarly, the T-flanged blades (3) are received into the tank (T) to be assembled or received into the tank (T) after assembly. The flanged blades (3) take the form of the anti-sloshing member (2) and are fixed by the locking element (5) in a position desired by the user in the tank (T) (Figure 8, Figure 9).

In an embodiment of the invention, the anti-sloshing mechanism (1) comprises a plurality of gaps (10) located on each blade (3); a plurality of protrusions (11) located on the locking element (5) so as to correspond to the gaps (10) on the blades (3) in a formcompatible manner, and which are inserted into the gaps (10) to enable the anti-sloshing member (2) to be fixed in the tank (T). Gaps (10) are provided on the blades (3) in order to fix the anti-sloshing member (2). In this embodiment, protrusions (11) are provided on the locking element (5) that are inserted into the gaps (10). In this way, the anti-sloshing member (2) is locked in the tank (T) in a position determined by the user. The protrusions (11) remain opposite to the gaps (10) and are inserted into the gaps.

In an embodiment of the invention, the anti-sloshing mechanism (1) comprises a plurality of holes (12) located on the blades (3) in geometric forms predetermined by the user, thus allowing the movement of the fuel in the tank (T) to not create sloshing and to be directed in a manner predetermined by the user. There are holes (12) on the blades (3) that allow the anti-sloshing members (2) to pass the fuel. Various geometrical holes (12) and/or axial openings are provided on the blades (3), at positions determined by the user, to allow fuel flow (Figure 7).

In an embodiment of the invention, the anti-sloshing mechanism (1) comprises the fuel tank (T) provided in air, space, land and/or sea vehicles.