EP2697435A1

EP2697435A1 - Method for filling and emptying a liquid tank of a spreader device for winter service vehicles, and spreader device

Info

Publication number: EP2697435A1
Application number: EP12734916.5A
Authority: EP
Inventors: Rolf Isele
Original assignee: Kuepper Weisser GmbH
Current assignee: Kuepper Weisser GmbH
Priority date: 2012-07-06
Filing date: 2012-07-06
Publication date: 2014-02-19
Anticipated expiration: 2032-07-06
Also published as: HRP20160627T1; RU2603765C2; WO2014005648A1; EP2682527B1; US10577766B2; US20150129689A1; EP2682527A3; PL2682527T3; DK2682527T3; EP2697435B1; RU2014129408A; KR20140138236A; HUE027880T2; CN104136687A; JP5878248B2; JP2015511284A; CN104136687B; EP2682527A2; ES2575162T3; CA2859263C

Abstract

In a spreader device (1) for winter service vehicles, brine is filled from a tank bag (40A) into supplementary tanks (10) by purely hydrostatic means substantially without the use of pumps by the tank bag (40A) being filled, for instance by means of overpressure, in such a way that the brine is forced through a liquid line (50, 50A) where it forms a closed liquid column. The outlet end of the liquid line (50) is located below the inlet end of the liquid line (50A) so that upon filling the liquid from the tank bag (40A) automatically flows into the supplementary tanks (10) on account of the hydrostatic forces. When the liquid tank (10) is drained, the liquid also flows correspondingly from the tank bag (40A) into the supplementary tanks (10), thereby draining the tank bag (40A) completely.

Description

Method for filling and emptying a liquid tank of a spreader for

Winter service vehicles and spreaders

The invention relates to a method for filling and a method for emptying a liquid tank of a spreading device for winter maintenance vehicles and a suitably designed for carrying out these methods spreader for winter maintenance vehicles and equipped with such a spreader winter service vehicle as such.

From the German patent application DE 10 2010 029 142 AI a spreader for winter maintenance vehicles is known, which combines three different scattering methods in itself, namely dry salt scattering, wet salt scattering and pure brine scattering. Normally, the brine for the wet salt dispersion and pure brine scattering is in an additional tank, for example, the side of the scattering container in which the road salt is stored, is mounted. Since the additional tanks are too small to sprinkle a standard scattering distance of about 50 km with pure brine, it is proposed in DE 10 2010 029 142 AI to use the scattering container either as another tank container for receiving brine. The additional tanks are retained in the event that wet salt is to be scattered and the scattering container is required to take solid Taustoffe. Instead of using the scattering container itself as another tank container, alternatively, a usable in the scattering tank tank bag can be provided. The brine required for the pure brine dispersion is conveyed from the additional tanks in a conventional manner and the additional tanks are automatically refilled from time to time with brine from the scattering tank or the tank bag received therein. The purpose of this is a pump which, via a hose projecting into the scattering container or tank bag, serves the purpose of rinsed brine into the additional tanks. As a pump, a suction pump 51, as shown in Figures 17 and 18, or alternatively serve a submersible pump.

However, the use of the pumps for the automatic filling of the additional tanks has proven to be prone to failure.

Object of the present invention is therefore to overcome this disadvantage of the prior art. This object is achieved by a method for filling and a method for emptying a liquid tank of a winter maintenance spreader and by a correspondingly adapted spreader with the features of the independent claims. In dependent claims advantageous developments and refinements of the invention are given.

The essence of the invention is to be seen in the fact that the automatic refilling of the additional tanks with brine from the scattering container or the tank bag inserted therein is achieved essentially solely by hydrostatic forces. By means of the solution according to the invention, however, it is not only possible to refill the additional tanks in continuous operation, but it is likewise possible to couple the initial filling of the additional tanks with the filling of the scattering container or of the tank bag received therein a step can take place. The different tank containers thus need not be filled separately, which means a significant relief and time savings.

Accordingly, the inventive method for filling a liquid tank, which includes as a first tank container such as the scattering container or the tank bag received therein and as one or more second tank container such as the aforementioned additional tanks, provides that the first tank container with the second tank or containers via a Liquid line is connected in such a way in that first the first tank container is filled with liquid, for example brine, until a moment when the liquid filled in the first tank container begins to flow through the liquid conduit into the at least one second tank container, the filling of the second container (s) Tank container with liquid from the first tank container through the liquid line therethrough following this moment.

This can in principle be done in two ways. Either one connects the liquid line in a lower region of the scattering container to this or the tank bag received therein and connects it preferably continuously downwards leading to the one or more auxiliary tanks, so that the liquid during filling of the main tank, ie the scattering container or the tank bag received therein, begins to flow directly into the additional tanks. If the height of the main tank overlaps with the height of the auxiliary tank (s) and the liquid level in the main tank rises, the liquid level in the additional tanks also rises until they are completely filled. Subsequently, the main tank can be filled up to the maximum filling volume. During the subsequent emptying of the liquid tank by removing the liquid from the additional tanks, the liquid level in the main tank first drops until it reaches the highest level of the additional tanks, whereupon the liquid level in the main and auxiliary tanks drops evenly during further emptying.

This first possibility of hydrostatic filling and emptying of the liquid tank is relatively easy to implement, if the scattering container itself is used as the first tank container, ie as the main tank. Because in this case, the liquid line can be connected in a relatively simple manner to the front sides of the main and auxiliary tanks. However, this is more problematic if, for example, a tank bag inserted in the scattering container serves as the first tank container or main tank. Because then the tank bag in a lower area of the scattering container must be connected to the scattering container wall or through this be performed. However, this lower region of the scattering container is difficult to access, especially if there is a tank bag therein. Since the use of a tank bag as the main tank over the use of the scattering container itself is to be preferred, offers the second possibility described below for hydrostatic filling and emptying of the liquid tank certain advantages.

According to this second possibility, the liquid line has a highest point between the two Leitungsöff openings at the respective ends of the liquid line. This highest point is preferably at or above an upper portion of the first tank (main tank), so that the step of filling the second tank (s) does not begin until the first tank is completely or at least almost completely filled. Namely, the filling of the second tank container (s) starts only after the liquid in the liquid line has reached the highest point, and thereafter the filling of the second tank container with liquid from the first tank container through the liquid pipe is made hydrostatic Forces automatically, namely as long as the line opening of the end of the liquid line projecting into the second tank container (additional tank) is below the liquid level of the first tank (main tank). This second possibility is not limited to the use of a tank bag as the first tank container but can also be used when considering certain boundary conditions, which will be explained below, if, for example, the scattering container itself is used as the first tank container (main tank). Preferably, the (first) line opening of the liquid line is close to the bottom of the first tank, so that the first tank container empties as completely as possible when emptying. For the same reason, the (second) line opening of the end of the liquid line connected to or projecting into the second tank container (auxiliary tank) is located at a position below the (first) line opening of the one connected to the first tank tank (main tank) protruding in the opposite end of the liquid line, so that the first tank container are emptied as deeply as possible when emptying the liquid tank. The (second) conduit opening is therefore preferably located below the bottom of the first tank container.

The liquid line can be guided over an upper edge of the scattering container. The highest point of the liquid line is then above the

Litter container or a received therein bag. On the one hand, this offers the advantage that the maximum filling volume of the first tank container

(Strainer hopper or stored therein tank bag) can be easily completely filled with liquid before the filling of the second tank container begins through the liquid line. The problem, however, is that in this case when using a tank bag as the first tank container, an overpressure must be built in the tank bag to force the liquid from the tank bag over the highest point of the liquid line out through the liquid line. It is also important that the liquid is pumped into the first tank container with such a volume flow that the liquid not only spills over the highest point but completely fills the liquid line. Because only with a closed column of liquid in the liquid line, the goal is achieved that the liquid is automatically retightened due to hydrostatic forces of the first tank into the second tank container.

If, on the other hand, the first tank container is not covered by a tank-bag but e.g.

is formed by the scattering container itself, the generation of an overpressure in the first tank container is not possible. For this case, for example, a suction pump can be provided on the liquid line, with which the liquid is sucked once beyond the highest point of the liquid line out. Subsequently, the suction pump can be switched off and the further BefüUvorgang runs automatically alone due to hydrostatic forces. The overpressure problem can be avoided if the liquid line is not guided around the upper edge of the scattering container but in an upper area through the wall of the scattering container. Then, the filling of the second tank container begins when the first tank container is almost completely filled and continues automatically, as long as it is ensured that forms a closed liquid column in the liquid line at the start of the independent filling, as previously explained.

In the upper region of the scattering container, the wall of the scattering container is relatively easily accessible even in the presence of a tank bag, so that the liquid line at this point can be easily passed through the wall of the scattering container to the tank bag or the tank bag at the appropriate location to an opening in the scattering container can be connected, at the opposite side then leading to the additional tank hose is connected.

The filling of the first tank can be stopped as soon as the second tank automatically fills due to the acting hydrostatic forces. The first tank then empties as the second tank container fills. Therefore, it is preferable to continue to fill the first tank container while the second tank container automatically fills with liquid from the first tank container until both tank containers are completely filled.

If, in later operation of the spreader, the liquid tank is emptied by branching off liquid from the second tank containers (auxiliary tanks), the liquid level in the first liquid tank (main tank, that is, scattering tank or tank bag) first drops until its liquid level reaches the level of the liquid tank highest second tank (additional tank) has dropped. Subsequently, the liquid levels in both tank containers decrease to the same extent until the (first) line opening in the first tank container protrudes above the liquid level. In this Moment rips off the liquid column in the liquid line. If the diameter of the liquid line is small and the capillary forces are sufficiently large, the liquid column located in the liquid line is retightened as the second tank container is further emptied. This effect is familiar to anyone in the context of straws. Therefore, it may be useful to form the liquid line from a bundle of lines of sufficiently small cross-section to promote this effect.

Preferably, vents are provided on the first and second tank containers, so that the air therein can escape to the extent that fills the corresponding tank container with liquid. Furthermore, a level limiter can be provided in the second tank container or in the first tank container, depending on the chosen filling principle, which sends a stop signal to the filling apparatus when a predetermined filling level has been reached.

The invention will now be described by way of example with reference to the accompanying drawings. Show:

FIG. 1 shows an isolated spreader according to a first exemplary embodiment in a perspective view,

various states during filling and emptying of the liquid tank of the spreader shown in Figure 1 schematically in cross section,

FIG. 10 shows a replacement diagram for the spreader according to FIGS. 1 to 9,

Figure 11 shows a schematic cross section through a spreader according to

th embodiment, FIG. 12 shows a schematic cross section through a spreader according to a third exemplary embodiment,

13 shows a schematic cross section through a spreader according to a fourth exemplary embodiment, FIG.

14 shows a schematic cross section through a spreader according to a fifth exemplary embodiment, FIG. 15 shows a schematic cross section through a spreader according to a sixth exemplary embodiment,

FIG. 16 shows a schematic cross section through a spreader according to a seventh exemplary embodiment,

FIG. 17 shows a spreader according to the prior art with a tank bag accommodated in the scattering container and

FIG. 18 shows the spreader according to the prior art from FIG. 17 without the tank sack.

Shown in Figure 1 is a top spreader 1 as a construction on a loading area of a truck, which is not explicitly shown here. On a welded support frame 2, a scattering container 3 is constructed, which has a funnel-shaped cross-section, so that collected in the scattering container Taustoffe collect on the conically converging bottom of the scattering container 3. A screw conveyor at the bottom of the scattering container transports solid scattering substances, in particular road salt, out of the scattering container 3 to an outlet 4, through which the scattering substances in turn gravitationally in the downpipe 5 a spreader 6 and through the downpipe 5 through a scattering plate 7 of the spreader. 6 can fall. Two additional tanks 10 for liquid, in particular for a salt solution (brine), are provided in order to admix the liquid which has fallen through the downpipe 5 in a suitably metered quantity of liquid. This is done in a conventional manner via a suction line 15 using a correspondingly controlled pump 16. The place of admixing does not necessarily have to be in the downpipe itself, but can also take place, for example, only at the lower end of the downpipe 5 on the spreading plate 7 ,

Further additional tanks 10 can be provided, for example, before the scattering container 3. In particular, the additional tanks 10 can be made significantly smaller in size in order to increase the content of the scattering container 3, as shown in FIG. If several additional tanks 10 are provided for mixing liquid detergents, they are preferably connected to one another via lines.

The functions pure brine spreading, dry salt scattering or wet salt scattering can be achieved with the pump 16 and suitable valves 11.2. By means of trained as a three-way cock valve 11.2 (for example ball valve), the pump 16 can be connected to the spray 17 or the downpipe 5 to see between the pure brine scattering and the Feuchtsalzstreuung. If dry salt is to be scattered, that is, without admixing brine from the additional tanks 10, either the pump 16 can be switched off or the three-way cock 11.2 can be pivoted so that the line path from the pump 16 to both the spraying device 17 and the scattering device 6 is interrupted. On the other hand, with the position of the three-way cock 11.2 shown in FIG. 1, it is also possible to disperse both dry salt by means of the spreading device 6 and pure brine by means of the spray device 17. By appropriate modification of the system, for example by other or additional directional valves and / or additional lines and / or line branches and / or by one or more further pumping It is also possible to ensure that brine is sprinkled over the spraying device 17 and moist salt via the spreader 6 at the same time.

In order now to increase the brine absorption capacity of the spreader 1, a liquid tank 40 is inserted into the scattering tank 3 and connected via a liquid line 50 to the auxiliary tanks 10. The liquid tank 40 can be filled with brine via a filler neck 42.

In addition to the filler neck 42, a feed-through nozzle 43 is provided, through which the liquid line 50 is led into the liquid tank 20 with a hose extension 50 A. The hose extension 50A extends to the bottom of the liquid tank 40. Thus, the liquid tank 40 can be completely emptied through the liquid line 50 and the additional tanks 10, ie in the specific embodiment of Figure 1 of the two additional tanks 10 connecting suction line 15, are fed.

In the exemplary embodiment according to FIG. 1, the liquid tank 40 is formed by a tank bag 40A, which is inserted in the scattering substance container 3 as described. For the purposes of the present invention, the tank bag 40A need not necessarily be made of a flexible, collapsible material, it may as well be a rigid insert tank. However, it is preferred if the tank bag, as described in DE 10 2010 029 142 AI, is flexible and collapsible, so that it is better storable. The tank bag 40 A fills only half of the scattering container 3 from. In the remaining other half, a second tank bag 40A or dry spreading material can be picked up, which is then conveyed under the tank bag 40A to the spreader 6. If a second tank bag 40A is provided, an overflow between the tank bags can be provided, which is arranged as far as possible above for easier operation. To the overflow of the second tank sacks then in turn joins a hose extension, which extends to the bottom of the second tank bag.

The principle of filling and emptying of the liquid tank is described below with reference to FIGS. 2 to 9, which is composed here of the first tank container formed by the tank bag 40A and by two additional tanks 10 as second tank container. The illustrations are to be understood purely schematically.

FIG. 2 shows a first phase of the filling process of the tank 40A. At this moment, the additional tanks 10 are still completely empty. The check valve 18 is closed. Instead of the check valve 18, the closing of the suction pipe 15 connected to the two auxiliary tanks 10 can also be ensured by the pump 16 alone (FIG. 1). According to the liquid level shown in FIG. 2, the tank bag 40A is not yet completely filled. The pressure acting on the liquid corresponds to the ambient pressure po. The arrow indicates that the tank bag 40A is further filled with liquid through the filler neck 42.

In Figure 3, the liquid level has risen so far that the vent valve 44 (see also Figure 1) closes. A float 45 in the vent valve 44 ensures that no liquid can escape from the tank bag 40A. The pressure acting on the liquid in the tank bag 40A at this time still corresponds to the ambient pressure po. The liquid level in the liquid line 50 has already risen above the tank bag 40A. Upon further filling of the tank bag 40A (FIG. 4), the pressure p acting on the liquid in the tank bag 40A is raised above the ambient pressure po. The tank bag 40A inflates (not shown) as indicated by the arrows in the tank bag, and the liquid in the tank bag 40A is forced through the liquid line 50 beyond the highest point 50B of the liquid line 50. This moment is shown in FIG. The one by the Filler 42 flowing volume flow is sufficiently large, so that the liquid over the highest point 50B of the liquid line 50 not only spills over, but as a closed liquid column, the liquid line 50 completely fills and flows down.

As soon as the liquid column has fallen below the lowest point of the tank bag 40 A, liquid automatically flows from the tank bag 40 A through the liquid line 50 into the right auxiliary tank 10 and also into the left auxiliary tank 10 via the connecting line 15. Figure 5 illustrates this principle. The level of liquid in the auxiliary tanks 10 increases in parallel as the liquid level in the tank bag 40 decreases. At this moment it is not necessary to continue to supply liquid through the filler neck 42 (however, this is advisable in order to keep the total filling time as short as possible). Figure 6 shows the state in which the liquid levels in all tank containers 40 A and 10 have reached the same level. There is no further liquid flows through the liquid line 50. The liquid level of the additional tanks 10 has risen to the leading up vent pipes 30. At least now, the filling process is continued by further supply of liquid through the filler neck 42 in the tank bag 40A. The liquid level in the vent tubes 30 continues to increase until the maximum fill volume is reached, as shown in FIG. Accordingly, the vent tubes 30 end above the highest fill level of the tank bag 40A. To empty the liquid tank, the check valve 18 is opened or the pump 16 is operated accordingly. Liquid is then withdrawn from the auxiliary tanks 10 through the suction line 15, and liquid flows from the tank bag 40A through the liquid line 50 into the auxiliary tanks 10 to the same extent as shown in FIG. The liquid level in all tanks 40A and 10 drops evenly until it reaches the lowest level shown in Figure 9, in which the conduit opening of the hose extension 50A projecting into the tank bag 40A emerges from the liquid level. From this moment, the further emptying of the liquid tank takes place solely from the additional tanks 10. Instead of the vent tubes 30, the auxiliary tanks 10 may also be equipped with vent valves 31, as shown in FIG. This vent valve 31 closes similar to the vent valve 44 of the tank bag 40A automatically when a correspondingly high level is reached. This torque can be detected by measurement and serve as a signal to adjust the further filling of the tank bag 40 A, which, however, only makes sense if the filling of the tank bag 40 A is continued, while the additional tanks 10 with out through the liquid line 50 liquid from Fill the tank bag with 40A.

FIG. 10 shows an equivalent circuit diagram for the spreader shown in FIG. Liquid is introduced into the tank bag 40A via a filler neck 42. The tank bag 40A vented via the vent valve 44 and the liquid is supplied via the liquid line 50 and hose extension 50A of the connecting line 14 between the two additional tanks 10 through which the liquid then flows into the auxiliary tanks 10. The two auxiliary tanks 10 are connected via vent pipes 30 to a common vent 30A which ends above the auxiliary tank 40A (not shown in the replacement diagram). A separate level limiter 32 is connected to one of the two additional tanks 10 and signals at a predetermined level the end of the filling process. Via lines 19, the additional tanks 10 are coupled to a manifold 20 which supplies the liquid from the additional tanks 10 either the scattering device 6 or another distributor 21, with which the liquid can be assigned to several spray heads 17A, 17B, 17C. FIG. 10 thus simultaneously represents a second exemplary embodiment as a deviation of the first exemplary embodiment, which is reproduced again schematically in FIG. Accordingly, here leads the liquid line 50 in a connecting line 14 between the two additional tanks 10, which is different from the manifold 20 leading to the suction lines 19, is withdrawn through the liquid from the additional tanks 10.

FIG. 12 shows, as a third exemplary embodiment, a further modification which has likewise already been explained in connection with the substitute diagram according to FIG. Accordingly, the vent tubes 30 of the auxiliary tank 10 terminate in a common vent 30A, which in turn is a self-closing valve that closes when the liquid level in the entire liquid tank has reached the vent 30A. This can, as mentioned, be detected by measurement and serve as a signal for switching off the filling process. Accordingly, in this third embodiment, the filler neck 42 is above the vent 30A, so that the filler neck 42 can be safely closed without liquid exiting the liquid tank.

FIG. 13 shows a fourth embodiment as a further modification. Here, the uppermost point 50B of the liquid line 50 is in an upper portion of the tank bag 40A immediately below the maximum fill level of the tank bag 40A. The liquid therefore flows from the tank bag 40A into the liquid line 50 when the maximum level in the tank bag 40A reaches approximately is without having to generate an overpressure in the tank bag 40A. The liquid line 50 then continues through in the upper region of the scattering container 3 through a wall 3A of the scattering container 3. Couplings 61 and 62 on the container wall 3A are provided to externally connect the liquid conduit 50 and internally the tube extension 50A thereto. This is also relatively unproblematic on the inside of the scattering container 3, because this point of the scattering container 3 is still easily accessible even in the presence of the tank bag 40 A. Figure 14 shows a further modification of a fifth embodiment in which the liquid line 50 in a lower region of the tank bag 40A, namely at the bottom of the tank bag 40A, attaches and steadily leading down to one of the two additional tanks 10 is connected. A horizontal arrangement of the liquid line 50 would also be possible. Again, the couplings 61 and 62 are again provided in the wall 3A of the scattering container 3, to connect the connection to the tank bag 40A on the inside and the connection to the additional tank 10 on the outside. FIG. 15 shows a sixth embodiment as a further modification. In this case, the first tank container (main tank) is not formed by a tank bag used in the scattering container but by the scattering container 3 itself. A sealing plate inserted into the hopper 3 plate 28 forms the bottom of the first tank. Underneath, the conveying device for conveying solid scattering substances runs in the event that the litter container 3 at other times does not serve as a liquid tank but in a conventional manner as a container for receiving, for example, road salt. The liquid line 50 is led into the scattering substance container 3 via a passage 63 in the wall 3A of the scattering substance container 3 and protrudes with its hose extension 50A to the bottom of the scattering substance container 3. The principle of filling and emptying corresponds to the previously described principle, in particular similar to that fourth embodiment according to FIG 13. If the liquid pressure when filling the tank container is not sufficient to produce a closed water column in the liquid line 50 to subsequently ensure an independent flow of liquid from the scattering container 3 in the additional tank 10, in addition, for example Suction pump 52 and a check valve 53 are provided. First, the check valve 53 is closed and then the suction pump 52 is put into operation. Once the suction pump 52 has sucked liquid, the suction pump 52 can be turned off and then the check valve 53 are opened. Then, the liquid flows automatically through the liquid line 50 from the scattering tank 3 into the auxiliary tank 10. Others Ways to start flowing through the fluid line 50 are also possible.

Finally, FIG. 16 shows a seventh exemplary embodiment as a further modification. As in the sixth embodiment, here the scattering container 3 itself serves as the first tank container (main tank) for receiving the brine, and similarly as in the fifth embodiment leads here the connecting line 50 from a lower portion of the scattering container 3 steadily downward leading or alternatively horizontally in the auxiliary container 10th ,

Instead of the scattering container 3, another tank can also serve as the main tank or "first tank." The above-described principles, in particular the use of a connecting line 50 passing through a highest point, can be applied thereto in the same way.

Claims

Patent claims

1. A method for filling a liquid tank (40 A, 10, 3, 10) of a scattering unit (1) for winter maintenance vehicles, wherein the liquid tank a first tank container (40A, 3) and at least one with the first tank container via a liquid line (50 , 50 A) connected to the second tank container (10) and wherein the first tank container (40; 3), for example a scattering substance container (3), which is coupled or can be coupled to a spreading device (6) for spreading solid substances received in the scattering substance container, or is a tank bag (40A) accommodated in the scattering substance container (3), characterized by the following steps:

Filling the first tank (40A; 3) with liquid, such as brine, until a moment when the liquid filled in the first tank (40A; 3) passes through the liquid line (50, 50A) into the at least one second tank container (10) begins to flow, and

Filling the at least one second tank container (10) with liquid from the first tank container (40A, 3) through the liquid line (10), following the aforementioned moment.

2. The method of claim 1, wherein the liquid line (50, 50A) has a highest point (50B) and the step of filling the at least one second tank vessel (10) begins and continues by utilizing hydrostatic forces after the liquid in the liquid line (50, 50 A) has reached the highest point (50B).

3. The method of claim 2, wherein the highest point (50B) of the liquid conduit (50, 50A) is at or above an upper portion of the first tank container (40A; 3), such that the step of filling the at least one second tank container (50A; 10) only begins when the first tank container (40 A, 3) is completely filled or at least almost completely filled.

4. The method of claim 3, wherein a maximum fill volume of the first tank (40A, 3) is completely filled with liquid before filling of the at least one second tank (10) begins.

5. The method according to any one of claims 1 to 4, wherein the filling of the first tank container (40 A; 3) during the filling of the second tank container (10) is continued.

6. A method for emptying a liquid tank (40A, 10, 3, 10) of a spreading device (1) for winter maintenance vehicles, wherein the liquid tank a first tank container (40A, 3) and at least one with the first tank container via a liquid line (50; 50 A) in the first tank container, preferably at the bottom of the first tank container (40 A; 3), and the first tank container (40 A; a scattering container (3), which is coupled or can be coupled to a spreading device for spreading solid substances collected in the scattering substance container, or is a tank bag (40 A) accommodated in the scattering substance container (3), characterized by the following steps: - removal of Liquid from the first tank container (40 A; 3) through the second tank container (10) by a second conduit opening of the liquid line (50) is arranged so that when removing the liquid from the second tank container (10) liquid from the first tank container (40A; 3) flows into the second tank container (10) solely on account of hydrostatic forces.

7. The method of claim 6, wherein the liquid line (50, 50A) is arranged such that a highest point (50B) of the liquid line (50, 50A) is between the first line opening of the liquid line (50) and the second line opening of the liquid line (50A).

A method according to claim 7, wherein the highest point (50B) of the liquid conduit (50, 50A) is at or above an upper portion of the first tank (40A; 3).

9. Spreader (1) for winter maintenance vehicles with a liquid tank (40A, 10, 3, 10), the at least one first tank container (40 A; 3) and at least one connected to the first tank container via a liquid line (50, 50A) second tank container (10), wherein the first tank container (40 A; 3), for example one

Litter container (3), which is coupled or can be coupled to a spreading device (6) for scattering solid substances collected in the scattering container, or is a tank bag (40 A) accommodated in the scattering container (3) and wherein the liquid line (50, 50A ) is connected to the first tank container (40 A; 3) with a first end and projects there and has a first conduit opening, preferably at the bottom of the first tank container (40A; 3), and with a second end to the at least second tank container (40). 10) is connected or protrudes therein and there has a second conduit opening, preferably at a location below the first conduit opening, wherein the liquid conduit (50, 50A) is arranged to dispense liquid from the first tank vessel (40A; 3) through the liquid conduit (50 , 50A) into the second tank container (10) without any means for actively conveying the liquid and only aufgru nd hydrostatic forces to transport.

10. The spreader according to claim 9, wherein the liquid passage (50, 50A) has a highest point (50B) between the first port and the second port which is at or above a top portion of the first tank (40A, 3) ,

11. spreader according to claim 9, wherein the liquid line (50, 50 A) between the first conduit opening and the second conduit opening steadily downward or horizontally leads.

12. Spreader according to claim 10 or 11, wherein the liquid line (50, 50A) passes through a wall (3a) of the scattering container (3).

13. Spreader according to one of claims 9 to 12, wherein the first tank container (40A, 3) has a first vent opening (44) which is adapted to

Air may escape through the first vent, while the first tank container (40A, 3) is filled with liquid by an opening (42) other than the first vent (44).

14. spreader according to one of claims 9 to 13, wherein the at least one second tank container (10) has at least one second vent opening (30; 30 A; 31) which is adapted to allow air to escape through the second vent opening during the at least one second tank container (10) is filled with liquid by an opening other than the second vent opening (30; 30A; 31).

15. winter maintenance vehicle comprising a spreader according to one of claims 9 to 14.