RU39592U1 - LIQUID OVERLOADING DEVICE - Google Patents

Abstract

To create a device for loading liquids, consisting of a loading arm with a gravity pipe for filling the tank, made in the form of a telescopic pipe with an outer pipe (4) and an inner pipe (2), in which the installation device or components of the installation device are not in the flow passing of liquid, it is proposed that the outer pipe (4) be mounted on the inner pipe (2) with the possibility of moving along the axis using the installation device (9), so that a protective tube is installed in the inner pipe (2) pipe (8), the upper end (1) of which came out with a seal, so that parts of the installation device (9) were installed in the protective pipe (8), extending at the lower end of the protective pipe, the details of which would be installed at the exit the ability to move through a blind flange (11) fixed to the neck of the protective pipe with a seal.

Description

DESCRIPTION

The invention relates to a device for transferring liquids, in particular gasoline and diesel fuel, consisting of a loading lever, preferably with several pipes, movably interconnected by articulated joints, and also with a gravity pipe to fill the tank, which is, for example, an integral part of a railway carriage and the gravity pipe is made in the form of a telescopic pipe with an outer pipe and an inner pipe.

A device of this kind is known from DE AS 20 41 650. In the known device, the outer pipe is held stationary, and the inner pipe is movable relative to the outer pipe. To move the inner pipe, a hydraulic cylinder is provided, mounted coaxially with the inner pipe and inside this inner pipe. Such an installation of the inside of the hydraulic cylinder is a disadvantage because the hydraulic cylinder with all seals and connections is inside the overloaded fluid stream. This fluid, while often talking about diesel fuel or gasoline, is very aggressive, so seals and connections are destroyed. For this reason, the device shown in the prior art, in practice was not successful.

Based on the prior art, the utility model is based on the task of creating a device of a similar type in which the installation device or components of the installation

the devices are not in the flow of the passing fluid, therefore, the destruction of the seals or connections of the passing fluid is prevented.

To solve this problem, according to a utility model, it is proposed that the outer pipe be mounted axially on the inner pipe, and this possibility was provided with the help of an installation device, a plate with a seal was installed in the outer pipe near its lower end, with the inner pipe the neck with the retracted outer pipe is adjacent to this seal, and so that the outer pipe near its lower end above the plate has at least one hole in the wall, so that in A protective pipe was installed on the bottom pipe, the top of which, in particular, protruded outward on the pipe elbow, which abuts the upper end of the inner pipe, and the outlet of the protective pipe relative to the inner pipe body was sealed so that parts of the installation device were installed in the protective pipe in particular, a pusher or rod, moreover, the pusher or rod protruded at the lower end of the protective pipe, at the exit point were sealed with a blind flange fixed to the neck of the protective pipe and outside the protective pipes connected to the plate of the outer pipe.

According to the utility model, the inner pipe is fixedly mounted, for example, on a dome-shaped sealing plate, which, when using the device, can be sealed in an open dome-shaped opening. The outer pipe is suitably installed with

the ability to move on the outer casing of the inner pipe. A plate with a seal is installed at the lower end of the outer pipe in the filling position. In addition, openings in the housing through which fluid may flow out are provided in the outer pipe body slightly above the plate. If the outer pipe is in the closed position, the seal plate seals the neck of the inner pipe so that liquid cannot escape. If the outer pipe by means of the installation device is moved to the flowing position, a gap is formed between the plate and the seal, on the one hand, and the lower neck of the inner pipe so that liquid can escape from the inner pipe. This liquid then flows through the openings in the outer pipe body into a refillable tank or the like.

In order to prevent the aggressive fluid passing through the pipes, the parts of the installation device are destroyed by the aggressive medium, a protective pipe is installed in the inner pipe, which extends to the upper bend of the inner pipe on the upper end of the inner pipe, and the outlet of the protective pipe is sealed relative to the inner casing pipes. Parts of the installation device are placed in a protective pipe, for example, a pusher or a rod for actuating and rearranging the outer pipe for actuating and moving the outer pipe. These parts of the installation device, in particular, the pusher or the rod, come out at the lower end of the protective pipe, and a blind flange is made at the exit site, through which part passes with the seal

installation device, in particular, a pusher or a rod. This ensures that liquid cannot enter the protective tube. Outside of the protective pipe, the end of the part of the installation device, in particular the end of the pusher or the end of the rod, is connected to a plate on which there is a seal that seals the neck of the inner pipe in the closed position.

By means of this arrangement, it is ensured that the installation device and, accordingly, the details of the installation device cannot be destroyed or damaged by a passing aggressive medium. High reliability is achieved for a long time.

A particularly preferred improved embodiment is seen in the fact that the installation device consists of a hydraulic cylinder located in the protective tube, the piston rod of which forms a pusher or rod, and the hydraulic cylinder pipelines are laid in the protective pipe and diverted to the upper end of the protective pipe.

In accordance with this embodiment, a hydraulic cylinder is installed in the protective pipe, the piston rod of which extends from the protective pipe on a blank flange and is connected to the outer pipe plate. The hydraulic cylinder itself, as well as the pipelines of the hydraulic system and their connecting parts are installed inside the protective pipe, and the pipelines of the hydraulic system are allotted to the upper end of the protective pipe and connected to the corresponding hydraulic accumulator, etc.

Alternative, under certain conditions, the preferred embodiment is seen in the fact that the installation device

consists of an electromechanical installation system with a linear actuator, in particular with a lead screw, the linear actuator being installed in a protective tube, connected to an external drive at the upper end of the protective tube and exits through the blind flange and connected to the plate at the lower end of the protective pipe outer pipe.

In this embodiment, the installation device is formed by an electromechanical installation system, whose linear actuator is, for example, a lead screw, which is installed in a protective tube. At the upper end of the protective tube, this lead screw, etc. can protrude and be connected to an external drive, or the external drive can also enter the upper neck of the protective tube. At the lower end of the protective tube, an actuator, in particular an element connected to the lead screw, emerges and is sealed with a blind flange, and at the end it is connected to the plate of the outer pipe.

In this case, in particular, it is provided that the linear actuator formed by the lead screw is connected to the drive, and the lead screw passes through more than half of the protective tube and is surrounded by a pipe segment having a master nut at the upper end through which the lead screw passes, and at the lower end a guide or support part is installed at the end of the lead screw, resting on the body of the pipe segment from the inside, and, moreover, the lower end of the pipe segment emerging from the blind flange of the protective pipe is hermetically connected en with an outer pipe plate.

In addition, it can be envisaged that the actuator is mounted on the upper end of the protective tube.

A particularly preferred improved embodiment is seen in the fact that the blind flange has a sealing system for sealing against a held part, which is resistant to aggressive media, such as diesel fuel or gasoline, and preferably consists of a combination of polytetrafluoroethylene with an elastomer.

To create a device of a type close to the genus, which is extremely functional and does not require large expenditures during manufacture, it is proposed that the gravity pipe be made in the form of a telescopic pipe with an outer pipe and an inner pipe, so that the outer pipe is mounted with the possibility of axial movement on the inner pipe so that the hydraulic cylinder is installed inside the inner pipe, is fixed with one end section on the upper end of the inner pipe, and its retractable pusher is fixed on the lower the end portion of the outer pipe, the outer pipe protruding downwardly from the inner pipe, that a plate with a seal is installed in the outer pipe near its lower end, the pusher is fixed to the plate, and the inner pipe with its lower neck is attached to the seal, and that the outer the pipe has at its lower end above the plate at least one hole in the wall.

The device according to the utility model is a hydraulically controlled system that allows you to lead to any loading position. Drawn position at her

passage is automated and brought with reproducible accuracy to the necessary loading position. Repetitions of the process are carried out, for example, after pressing a key in the control system of the device. In doing so, the requirements of the Technical Manual for Air Pollution Protection (TA-LUFT) are complied with. In the device according to the utility model, loading arms of a conventional design are used, consisting of movable pipes movable on articulated joints in all planes. At the end of the loading arm, a corresponding gravity pipe is installed in the form of a telescopic pipe system, which complements the device. The telescopic pipe consists of an external gravity pipe, which can be fed and discharged inside the hydraulic cylinder. The hydraulic cylinder is located in the current transported medium, such as gasoline or diesel fuel. In particular, the hydraulic cylinder is installed in a protective tube that stabilizes the entire device and protects the hydraulic cylinder.

The pipes forming the telescopic system are not cylindrically sealed, but are only centered by two guide bushings in the form of slide bushings. One of these guide bushings is fixed on the upper end portion of the movable outer pipe, and the second guide bush on the lower portion of the inner gravity pipe. When retracting the outer pipe, the inner pipe is axially sealed with a seal in the bottom-forming plate mounted near the lower end portion of the outer pipe. This is necessary so that the incoming medium cannot

to leak, as a result of which the environment and the filling tank would be contaminated. A sealing plate with a seal is fixed above the inserted outer pipe at the outwardly protruding end of the inner pipe, which lies in the state of filling on the dome of the tank and seals the system from the outside. This plate may further comprise openings for passage of gasoline vapor into the space located above the plate.

Preferred embodiments of the utility model are indicated in dependent paragraphs 8-11 of the utility model formula.

Examples of the utility model are shown in the drawing and are described below in more detail. Shown:

figure 1 - the first embodiment of the utility model in longitudinal section in the middle in the closed position;

figure 2 is the same in the position of the duct;

figure 3 is an option in the position of figure 1;

figure 4 - is essential for a utility model part of the loading device in the closed position in a side view in section;

5 is a detail of figure 4 in the open position in the same form.

The drawing shows only the essential part of the device of interest in this case. The device as a whole consists of several pipes hinged to each other, forming a loading arm. As the last part of this loading device is the element shown in the drawing. It has an attachment to the swivel joint of the next loading arm. From this connection through the elbow 1 of the pipe, the inner pipe 2, which is an integral part of the telescopic pipe, leaves vertically down. For loading liquid

the block shown in the drawing can be inserted in the tank dome, and in the loading position on the dome there is a sealing dome plate 3 fixedly mounted on the upper end of the inner pipe 2. Another component of the device is the outer pipe 4, mounted on the housing of the inner pipe 2 with axial moving and moved by the installation device described below in different positions. On the outer pipe 4, at its lower end, a plate 5 with a seal 6 is fixed. In an unused position, when the outer pipe is retracted, the plate 5 with a seal 6 abuts the neck of the inner pipe 2 so that it closes. In the passage position shown in FIG. 2, the openings 7 in the wall of the outer pipe 4 are released and the seal 6 is located at a distance from the lower end of the inner pipe 2 so that liquid can escape through the openings 7 in the wall from the inner pipe and drain into the corresponding vehicle -tank, etc.

Additionally, a protective pipe 8 is installed and fixed in the inner pipe 2, the upper end of which on the elbow 1 of the pipe exits. The exit point of the protective pipe 8 is sealed relative to the housing of the inner pipe in the passage section. In the protective pipe 8 there are placed parts of the installation device 9, for example, a pusher 10 and the like. comes out at the lower end of the protective tube 8. At the exit site, a pusher 10 is sealed with a possibility of movement through a blind flange 11 fixed to the neck of the protective pipe. Outside the protective pipe 8, the end of the pusher 10, etc. rigidly connected to the plate 5.

In the embodiment of figure 1 and 2 installation device

9 consists of a hydraulic cylinder 12 located in the protective tube 8, the piston rod of which forms a pusher 10, the hydraulic pipes 13, 14 of the hydraulic cylinder 12 being laid in the protective pipe 8 and allotted to the upper end of the protective pipe 8. Thus, all connections, seals and pipelines hydraulic systems are installed protected inside the protective pipe 8 and cannot be damaged by aggressive fluid flowing through pipes 2 and 4, respectively.

In the embodiment of FIG. 3, the installation device 9 consists of an electromechanical installation system with a linear actuator, in particular a lead screw 15. The linear actuator 15 is installed in the protective pipe 8 and is connected to the external drive 16 at the upper end of the protective pipe 8. At the lower end of the protective pipe 8, an organ 15 protrudes, sealed with a blind flange 11, the free end being also connected to the plate 5 of the outer pipe 4. The drawing shows an open position in which the plate 5 with a seal 6 on runs at a distance from the lower end of the inner pipe.

The linear actuator formed by the lead screw 15 is appropriately connected to the drive 16, the lead screw extending over more than half the length of the protective tube 8 and is surrounded by a length of pipe 17, which has a master nut 18 at the upper end through which the lead screw 15 passes. at the end of the lead screw 15, a guide or supporting part 9 is fixed, resting on the body of the pipe section 17, located inside. The lower end of the pipe segment 17 emerging from the blank flange 11 of the protective pipe 8 is connected to the seal with

by the plate 5 of the outer pipe 4. The drive 16 is preferably mounted on the upper end of the protective tube 8. By actuating the drive, the outer pipe 4 can be put into the passage position in accordance with FIG. 3 or in the closed position similarly to FIG. In this case, again, all the elements of the installation device are placed inside the protective pipe 8 so that they are protected from aggressive environments.

Blind flange 11 has, in particular, an appropriate sealing system for sealing against parts that have passed through it, which is resistant to aggressive media, such as diesel fuel or gasoline. It preferably consists of a combination of polytetrafluoroethylene (PTFE-Compounds) with an elastomer.

In the drawings of FIGS. 4 and 5, only the essential part of the device of interest is shown. The device as a whole consists of several pipes interconnected by joints that form a loading arm. As the last part of this loading device, the element shown in the drawing is provided. It has connection 1 on the swivel joint of the loading arm. From this connection, through an approximately rectangular bend, a pipe leaves downward at an angle, which forms the inner pipe 2 of a gravity pipe made in the form of a telescopic pipe. On this gravity pipe in the area of the upper bend held and fixed protective pipe 8, which passes in the center through the inner pipe 2 to its neck. A hydraulic cylinder is installed in this protective pipe, and the hydraulic connections 20 are freely accessible from the outside of the pipe

2. At the lower end, the plunger 10 of the hydraulic cylinder located in the protective tube 8 comes out and is rigidly connected to the plate 5. This plate is connected to the outer pipe 4 of the telescopic pipe and closes the free cross section of the outer pipe at the lower end.

Into the corresponding annular groove, etc. of this plate 5, a seal 6 is laid. In the retracted position of the outer pipe 4 shown in FIG. 4, the opening of the neck of the inner pipe 2 is located in the seal 6 so that the liquid cannot escape. When the outer pipe 4 with the help of the pusher 10 of the hydraulic cylinder extends to the loading position, then, as shown in Fig. 5, a liquid, for example gasoline or diesel fuel, flows out along the arrow 21 from the neck of the inner pipe and flows through the openings 7 in the wall of the outer pipe . These holes 7 are made almost above the plate 5 in the wall of the outer pipe 4. In addition, guiding sleeves 22 lying on the outside and fixed at the upper end of the outer pipe 4 inside and at the lower end section of the inner pipe 2 are additionally fixed. Additionally, the protective tube 8 contains near its lower end surrounded by an inner tube 2, ribs 23 for centering.

24 indicates the dome of the tank. In the loading position on the dome 24 of the tank is a sealing plate 3 of the dome, rigidly fixed to the upper end of the inner pipe. A dome-shaped hollow space is formed above the sealing plate of the dome, formed by part 25 in the form of a bell, which is mounted on the sealing plate 3 of the dome and on the housing

inner tube 2. In the sealing plate 3 of the dome, openings 26 are provided through which gasoline vapors can escape, which can be discharged through outlet 27, for example, via a hose, and reintroduced into the system.

To fill the tank, the loading arm with gravity pipes is correctly set to the position of FIG. 4 and inserted into the dome of the tank, as explained in FIG. 4. Since then the liquid must be poured into the tank, the hydraulic cylinder located in the protective tube 8 is actuated so that the pusher 10 moves to the position shown in FIG. 5. Thus, the outer pipe 4 is advanced relative to the inner pipe 2 downward so that the neck of the inner pipe 2 is released, and the corresponding liquid can flow out, which can then drain through the openings 7 in the wall of the outer pipe 4 into the tank. At the end of the filling process by actuating the pneumatic cylinder, the pusher 10 is again rearranged in the initial position in FIG. 4 so that the neck of the inner pipe 2 is sealed with a seal 6, and further liquid exit is prevented. Preferably, the openings 7 in the wall are exactly above the plate 5, as shown in FIG. 5 so that no liquid remains in the outer pipe, but they can completely drain through the openings 7.

The utility model is not limited to an example of implementation, but within the framework of the disclosure it can be varied.

All new individual features and features disclosed in the description and / or drawings are considered to be essential features of the utility model in combination.

Claims (11)

1. Device for transshipment of liquids, in particular gasoline and diesel fuel, consisting of a loading arm with several pipes movably interconnected by swivel joints, and also with a gravity pipe to fill the tank, which is, for example, an integral part of a railway carriage, and gravity the pipe is made in the form of a telescopic pipe with an outer pipe (4) and an inner pipe (2), characterized in that the outer pipe (4) is mounted on the inner pipe (2) with the possibility of movement along the axis with by mounting device (9), in the outer pipe (4) near its lower end there is a plate (5) with a seal (6), and the inner pipe (2) with its lower neck with the retracted outer pipe (4) is adjacent to the seal (6) and the outer pipe (4) near its lower end above the plate (5) has at least one hole (7) in the wall, a protective pipe (8) is installed in the inner pipe (2), the upper end of which comes out in particular, on the elbow (1) of the pipe, which is adjacent to the upper end of the inner pipe (2), and the exit point of the protective the pipes (8) are sealed relative to the walls of the inner pipe (2), the parts of the installation device (9) are installed in the protective pipe (8), in particular the pusher or the rod, the pusher or the rod coming out at the lower end of the protective pipe (8), in a place the outlet passes with the possibility of movement with sealing through a blind flange (11), mounted on the neck of the protective pipe, and outside the protective pipe (8) is connected to the plate (5) of the outer pipe (4). 2. The device according to claim 1, characterized in that the installation device (9) consists of a hydraulic cylinder (12) installed in the protective tube (8), the piston rod (10) of which forms a pusher or rod, and, if necessary, seals and pipelines ( 13, 14) of the hydraulic cylinder (12) are laid in the protective tube (8) and retracted at the upper end of the protective tube (8). 3. The device according to claim 1, characterized in that the installation device (9) consists of an electromechanical actuator system with a linear actuator (15), in particular a spindle, the linear actuator (15) installed in a protective pipe (8), at the upper end of the protective pipe (8) it is connected to an external drive (16), at the lower end of the protective pipe (8) it exits through a blind flange (11) and is connected to the plate (5) of the external pipe (4). 4. The device according to claim 3, characterized in that the linear actuator (15) formed by the lead screw is connected to the drive (16), the lead screw (15) extending over more than half the length of the protective tube (8) and surrounded by a segment (17) ) a pipe that has a uterine nut (18) at the upper end through which the lead screw (15) passes, with a guide or support part (19) mounted on the lower end of the lead screw (15), resting on the pipe section (17) with the inner side, and, moreover, the lower end of the pipe segment (17) emerging from the blind ANCA (11) of the protective tube (8) is sealingly connected to the plate (5) of the outer tube (4). 5. The device according to claim 4, characterized in that the actuator (16) is mounted on the upper end of the protective tube (8). 6. The device according to one of claims 1 to 5, characterized in that the blind flange (11) contains a sealing system for sealing against parts passing through it, resistant to aggressive media, such as diesel fuel or gasoline, and preferably consisting of a combination of composition polytetrafluoroethylene with an elastomer. 7. The device according to claim 1, characterized in that the gravity pipe is made in the form of a telescopic pipe with an outer pipe (4) and an inner pipe (2), the outer pipe (4) is mounted with the possibility of axial movement on the inner pipe (2), inside the inner pipe (2) a working cylinder is installed, in particular a hydraulic cylinder or an electromechanical cylinder, fixed by an end section at the upper end of the inner pipe (2), and a retractable pusher (10) which is fixed on the lower end section of the outer pipe (4), the outer pipe (4) extends downwardly behind the inner pipe (2), in the outer pipe (4) near its lower end there is a plate (5) with a seal (6), the pusher (10) mounted on the plate (5) and the inner pipe (2) with its lower the neck with the retracted outer pipe (4) is adjacent to the seal (6), and the outer pipe (4) near its lower end above the plate (5) contains at least one hole (7) in the wall. 8. The device according to claim 7, characterized in that the inner pipe (2) protrudes above the outer pipe (4) and has a domed sealing plate (3) on the protruding section. 9. The device according to claim 7, characterized in that the slide bushings (22) are installed as supports on the upper end of the outer pipe (4) and on the lower end of the inner pipe (2). 10. The device according to claim 7, characterized in that centering ribs (23) are provided on the housing of the hydraulic cylinder. 11. The device according to claim 7, characterized in that the hydraulic cylinder is installed in a protective pipe (8).