DE102018208312A1 - Storage pot bottom of a storage pot - Google Patents

Abstract

The technology disclosed herein relates to a storage pot bottom 100 of a storage pot. The storage pot bottom 100 comprises: i) at least one inlet 110 for the flow of resources into the storage pot and ii) a plurality of channels 131, 133, 135 for the transport of resources. The channels 131, 133, 135 are each tapered from the peripheral region to the center of the storage pot bottom 100.

Description

The technology disclosed herein relates to a storage pot bottom of a storage cup for a resource container. A resource container may be, for example, a fuel tank of a motor vehicle in which fuel is stored. Such fuel tanks comprise a swirl pot into which i.d.R. Fuel is supplied via an inlet at the storage pot bottom. In previously known solution i.d.R. a resource pump used. The specific design of the storage pot bottom affects the size of the resource pump. A larger resource pump may require more electrical power. Furthermore, a larger resource pump may require more space in the space-critical storage tank. Furthermore, the heat output may increase, which may increase the resource evaporation.

It is a preferred object of the technology disclosed herein to reduce or eliminate at least one disadvantage of a previously known solution or to suggest an alternative solution. In particular, it is a preferred object of the technology disclosed here to enable the use of the smallest possible resource pump or to transport equipment from the resource container into the storage pot as energy-efficiently as possible. Other preferred objects may result from the beneficial effects of the technology disclosed herein. The object (s) is / are solved by the subject matter of claim 1. The dependent claims are preferred embodiments.

In particular, the technology disclosed herein relates to a storage pot bottom of a storage pot for a resource container of a motor vehicle. A resource container forms the storage volume for storing the resource. The resource container thus forms the substantially fuiddichte outer shell of the storage volume and limits the storage volume relative to the installation space. In the case of plastic containers, for example, one speaks of the bubble. In the case of steel fuel tanks, the resource container may be formed, for example, of two metal shells. Advantageously, the resource container may have a saddle shape, with a main chamber and a secondary chamber, which are connected to each other via a connecting portion.

The container disclosed here further comprises a storage pot in which at least one inlet or an inlet opening (hereinafter for the sake of simplicity: only the term "inlet" is used, which should comprise both) is arranged to convey the operating medium. Such a storage pot may preferably be formed as a swirl pot. The storage pot is usually arranged at the bottom of the resource container and extends in the direction of the motor vehicle vertical axis Z (from the drawing level of the 1 pointing direction). The storage pot is used to stockpile a certain volume of resources, which is promoted by a in the resource container, preferably in the storage cup, arranged pump to any resource consumers. It is also conceivable that the pump is arranged outside of the resource container for storing the liquid operating means. The volume of the storage tank is very small compared to the storage volume of the resource tank. For example, the volume of the storage pot may be at least a factor 10 , preferably at least by a factor 50 , and more preferably at least by a factor 100 , less than the storage volume of the resource container. At the bottom of the storage tank, the inlet for the flow of resources is provided in the storage tank. Preferably, an element of the resource pump may be provided immediately adjacent to the inlet. This may be, for example, the operating fluid pump itself or a suction point fluidically connected to the operating fluid pump.

The storage pot bottom may be formed integrally with the storage pot, for example by injection molding or blow molding. In another embodiment, the storage pot bottom can be attached to an underside of the storage pot in a form-fitting, cohesive or force-fit manner. For example, the storage pot bottom can be configured as a base plate fastened via latching hooks. As a rule, the storage tank bottom is in the installation position on the equipment container bottom.

• - mindestens 0,15 D; oder
• - von mindestens 0,25 D; oder
• - von mindestens 0,3 D

vom Mittelpunkt des Speichertopfbodens angeordnet sein. D ist dabei der Abstand zweier gegenüberliegenden äußeren Seitenbereiche des Speichertopfbodens entlang der Achse, die der Mittelpunkt und der Mittelpunkt vom Zulauf bilden. Bevorzugt kann ein Bereich von 0 ,1D bis 0,5D vorgesehen sein. Bei einem im Wesentlichen runden Speichertopfboden ist D der äußere Durchmesser des Speichertopfbodens.According to the technology disclosed herein, the inlet for the flow of resources in the storage pot bottom (also) is formed. In one embodiment, the at least one inlet can be formed in the middle of the storage pot bottom. Alternatively or additionally, the inlet can be designed decentralized. For example, the inlet may be arranged at a distance from the center of the storage pot bottom. For example, the center of the inlet at a distance of

• - at least 0,15 D; or
• - of at least 0.25 D; or
• - of at least 0.3 D

be arranged from the center of the storage cup bottom. D is the distance between two opposite outer side areas of the storage cup bottom along the axis, which form the center and the center of the inlet. Preferably, a Range from 0, 1D to 0.5D be provided. For a substantially round storage pot bottom, D is the outer diameter of the storage pot bottom.

The storage pot bottom further comprises a plurality of radially oriented channels for transporting operating means, in particular from the peripheral region of the storage pot bottom to the center of the storage pot bottom. The peripheral region is the region of the storage pot bottom, which is formed immediately adjacent to the outer edge of the storage pot bottom. It is within the distal range disclosed herein.

The channels may each be tapered from the peripheral region to the center of the storage pot bottom. In particular, the channels may be tapered so that, at least at the proximal end of the channels relative to the center of the reservoir bottom, the pressure is higher than at the beginning of the channels distal to the center of the reservoir cup bottom.

The channels may be formed on the storage pot bottom such that at least 25% or at least 50% or at least 75% of the kinetic energy of operating fluid flowing into the channels is converted to static pressure. The channels can be arranged in such a way that operating medium striking the edge of the storage pot bottom substantially from all directions can flow into the channels without having to be surrounded by the storage pot bottom in the circumferential direction by more than a quarter or one fifth of the outer peripheral surface. The outer peripheral surface is defined by the outer edge of the storage pot bottom. Advantageously, therefore, can thus flow directly into place in the channels on the storage pot bottom incident on the ground, without losing previously by unnecessary deflection outside the storage pot bottom kinetic energy. The channels then convert the kinetic energy into static pressure. Advantageously, by such an embodiment, the kinetic energy of sloshing from different directions resources can be used.

According to the technology disclosed herein, the individual channels of the plurality of channels may each be formed by two adjacent lands. Preferably, the webs each have a substantially constant web width or thickness. Particularly preferably, the webs are formed integrally with the storage pot, in particular by injection molding. Particularly preferably, the webs are from an outer surface of the storage pot bottom in the installed position downwards from. But this does not have to be this way. The channels or the webs are expediently arranged and configured in such a way that at least 80% or at least 90% and preferably 100% of the fuel passes via the channels to the center of the storage pot bottom. For this purpose, for example, the webs in the installed position at least partially rest on the resource tank bottom and / or the gap between resource tank bottom and top of the webs can be so low that only negligible amounts of resources do not flow through the channels. Preferably, the channel-forming webs are continuous walls of the channels and have no interruptions.

The webs or channels can begin in a distal region with respect to the inlet and open into a region proximal to the inlet. The distal region may be an area at least 0.3 D or at least 0.4 D or at least 0.45 D away from the center of the reservoir well bottom, wherein D the distance between two opposite outer side portions of the storage cup bottom is. In a substantially round storage pot bottom is D the outer diameter of the storage cup bottom.
The proximal region may be an area that terminates at a maximum of 0.25 D or a maximum of 0.2 D or a maximum of 0.15 D from the center, wherein D the diameter of the storage cup bottom is, where D the distance between two opposite outer side portions of the storage cup bottom is. In a substantially round storage pot bottom is D the outer diameter of the storage cup bottom.

Thus, therefore, the distal region is formed immediately adjacent to the outer edge or peripheral region of the storage pot bottom or comprises this, whereas the proximal region is formed directly adjacent to the edge of the inlet. The proximal or distal region may in particular be circular (ring) regions.

Preferably, the channels or the webs may be formed substantially arcuate. In this case, the arcuate shape can be realized by a continuous arcuate course or an arcuate course can be approximated by straight portions arranged in succession. Preferably, the webs or the channels in the plan view of the underside of the storage pot bottom and seen in the radial direction in the same direction curved or arc-shaped in the same direction, in particular concave.

• - zwischen 185 ° und 355 ° oder
• - zwischen 270° und 355° oder
• - zwischen 315° und 345°.

The webs may be substantially U-shaped or V-shaped, and wherein the central axes of the webs are radially oriented. The two ends of at least one web are then arranged further inwards than the middle regions of the same webs. The middle areas are the areas in which the webs change their direction by more than 180 °. The middle areas are thus the Areas of the webs with a reversal of direction of the webs. Preferably, these center regions are arranged directly adjacent to the outer edge in the peripheral region or in the distal region. The flanks of a web can form an outer angle α, which assumes a value

• - between 185 ° and 355 ° or
• - between 270 ° and 355 ° or
• - between 315 ° and 345 °.

Preferably, the ends of the lands may be concentric with the center of the reservoir cup bottom and / or immediately adjacent (i.e., less than 20mm or less than 10mm or less than 5mm) from the ends of the flow directors disclosed herein.

In one embodiment, further flow guide elements can be provided, which are set up to at least partially divert resources emerging from the channels.

The flow guiding element may be configured to at least partially direct the operating medium flowing out of a (first) channel of the channels into interior regions of those adjacent webs which form this (first) channel. The interior area is, for example, the area that the i.d.R. form diverging flanks of a suitably U-shaped or V-shaped web.

Such flow guide elements can be arranged substantially oriented in the circumferential direction. Advantageously, such flow guiding elements can also reduce the probability that the operating medium that has already flowed into the proximal region flows out into the channels again.

Preferably, the flow guide elements are rotationally symmetrical to the center of the storage cup bottom.
Suitably, the flow guiding elements can be substantially concentric with the center M be arranged.

Further advantageously, an inflow gap is provided between two flow guide, can flow through the resource to the center before it reaches the inlet. Particularly preferably, the inflow gaps are arranged in the region of the center axes of the webs. Further preferably, the Einströmspalte in the plan view of the underside of the storage pot bottom and in the radial direction are curved in the same direction or curved in the same direction, in particular convex.

At least one solid filter may preferably be provided on the storage pot bottom, in particular in the proximal region and / or in the distal region and / or between two webs. For example, a solids filter may be provided at the edge of the inlet. Alternatively or additionally, a solids filter may be provided on the outer edge of the storage pot bottom.

The solids filter is set up to at least partially hinder solids contained in the operating medium from penetrating into the storage pot or into the operating medium pump. Conveniently, the particulate filter is formed by a plurality of protruding elements which protrude from an outer storage pot bottom surface. The individual protruding elements are arranged one below the other at such a small distance that the operating medium can flow through, but not the solids. Such a solid filter is also referred to as a "rock stopper" and serves to protect the resource pump.

A preferred resource is fuel. Similarly, it is conceivable that the technology disclosed herein may be used to store other liquids (e.g., water or an aqueous solution) in a motor vehicle. Even if there is talk of a resource tank, resource pump and the like, so should the terms fuel tank or fuel pump to be disclosed with.

With the technology disclosed herein, it is advantageously possible to operate the fuel supply system more energy-efficient overall. Thus, the heat input into the fuel can be reduced. Furthermore, a smaller sized resource pump can be used, whereby i.d.R. Space, weight and costs can be reduced. The solution disclosed here can be easily manufactured by previously known methods. Furthermore, no moving parts are used. Thus, the technology disclosed here is also low maintenance.

• 1 eine schematische Ansicht von unten auf einen Speichertopfboden 100;
• 2 eine schematische Ansicht von unten auf einen weiteren Speichertopfboden 100;
• 3 eine schematische Ansicht von unten auf einen weiteren Speichertopfboden 100;
• 4 eine schematische Ansicht von unten auf einen weiteren Speichertopfboden 100; und
• 5 eine schematische Ansicht von unten auf einen weiteren Speichertopfboden 100.

The technology disclosed herein will now be explained with reference to the figures. Show it:

• 1 a schematic view from below of a storage pot bottom 100 ;
• 2 a schematic view from below of another storage pot bottom 100 ;
• 3 a schematic view from below of another storage pot bottom 100 ;
• 4 a schematic view from below of another storage pot bottom 100 ; and
• 5 a schematic view from below of another storage pot bottom 100 ,

The 1 shows an embodiment of the storage pot bottom disclosed here 100 , The neighboring footbridges 130 . 132 make up the channel here 131 out. As it were, the bridges form 132 . 134 the channel 133 off and the jetties 134 . 136 the channel 135 , The bridges 130 . 132 . 134 . 136 start here in the proximal area 150 from the storage cup bottom 100 and each extend to the outer edge 144 out. At the outer edge 144 Here are the middle areas of the bridges 130 . 132 . 134 . 136 provided, in which here two flanks of a bridge converge each. The center areas are here the areas in which a reversal of direction of the respective web takes place, whereby the direction changes by more than 180 °. In other words, the flanks of each web form an outside angle α , which takes a value of about 340 °. But it could also be another outside angle α be provided. The bridges 130 . 132 . 134 . 136 here all have the same outer angle α. But this does not have to be this way. The bridges 130 . 132 . 134 . 136 have here a substantially constant web width. The bridges 130 . 132 . 134 . 136 are V-shaped. The bridges 130 . 132 . 134 . 136 are arranged here substantially radially oriented. The central axes (shown in phantom) extend from the midpoint M the storage cup bottom 100 radially outward. The open side of the V-shape of the webs 130 . 132 . 134 . 136 points to the center here M out. The closed center area of a first bridge 132 is located radially farther outward than the two ends of the first ridge 132 , The two flanks of the jetty 132 extend from the center region to the two ends. They are arranged divergently here. The two flanks form an interior area here I out, in from the neighboring channels 131 . 133 Can flow in resources. As it were, here are the other bridges 130 . 134 . 136 educated. The distal area 140 is here from the outer edge 144 and from the dot-dash line 142 limited. The proximal area 150 extends here from the center M to the dashed line 152 , Within the proximal area 150 here is the solids filter 160 intended. But this does not have to be this way. Alternatively or additionally, a solids filter 160 on the outer edge 144 be provided.

This can, for example, concentric to the center M or concentric to the inlet 110 be educated. Also concentric to the center M or to the inlet 110 Here are the flow guide 170 . 172 . 174 . 176 or the webs 130 . 132 . 134 . 136 arranged. The ends of the flow guide 170 . 172 . 174 . 176 or the inflow column 171 . 173 . 175 are also concentric to the center here M intended. However, such a concentric arrangement of the aforementioned elements need not be realized.

The flow guide elements 170 . 172 . 174 . 176 are here arcuate. Viewed in the plan view and in the radial direction outward, these flow guide elements 170 . 172 . 174 . 176 Convex shaped. Through a first channel 133 entering equipment is through the flow guide 172 divided and for the most part introduced into the interiors I of the adjacent webs 132 . 134 , The bridges 130 . 132 . 134 . 136 and the flow guide elements 170 . 172 . 174 . 176 are formed and arranged such that the resource from the interior areas I or partially after the deflection by the flow guide 170 . 172 . 174 . 176 directly into the inflow column 171 . 173 . 175 flows in and thus in the proximal region 150 arrives. The flow guide elements 170 . 172 . 174 . 176 are also set up here, already in the proximal area 150 Ingressed fluid at the outflow into the channels 131 . 133 . 135 at least hamper. The feed 110 includes a border 154 , The bridges 130 . 132 . 134 . 136 end here at the proximal area 150 , The flow guide ends here almost at the same radial distance as the ends of the flow guide 170 . 172 . 174 . 176 , But that does not have to be this way.

The channels 131 . 133 . 135 allow here the flow of equipment from essentially all directions. At least to the proximal area 150 towards the rejuvenate the channels 131 . 133 . 135 , reducing the pressure in the channels 131 . 133 . 135 is increased. The resource thus comes with a compared to the distal area 140 increased pressure in the inlet 110 ,

The storage pot bottom 100 includes 8 webs, 8 channels, 8 flow guides and 8 inflow gaps, of which only the webs 130 . 132 . 134 and 136 , the channels 131 . 133 . 135 , the flow guide elements 170 . 172 . 174 . 176 and the inflow column 171 . 173 . 175 are provided with reference numerals. Similarly, a larger number of webs, channels, flow guide, flow guide or inflow or a smaller number of webs, channels, flow guide or Einströmspalte could be provided. The same applies to the embodiments explained below according to the 2 to 5 ,

The 2 shows a further embodiment of the storage pot bottom disclosed here 100 , Hereinafter, only the differences in comparison with the embodiment according to the 1 explained. The storage pot bottom shown here 100 has webs 130 . 132 . 134 . 136 that are not pointed here, but that are rounder. Furthermore, the outside angle is α here about 330 °.

The 3 shows a further embodiment of the storage pot bottom disclosed here 100 , Hereinafter, only the differences in comparison with the embodiments according to the 1 or 2 explained. The feed 110 of the storage pot bottom shown here 100 is decentralized here. He is from the center of the storage pot floor 100 spaced apart. Such a configuration may be advantageous in terms of the arrangement of the components in the storage pot. Despite the decentralized arrangement of the inlet 110 Here are the individual bridges 130 . 132 . 134 . 136 arranged rotationally symmetrical. Only the jetty 180 is designed bulbous here and at least partially encloses the inlet 110 , The solid filter 160 here is concentric to the inlet 110 intended.

The 4 shows a further embodiment of the storage pot bottom disclosed here 100 , Hereinafter, only the differences from the previous embodiments according to the 1 to 3 explained. In this embodiment, the ends of the webs 130 . 132 . 134 . 136 as well as the flow guide elements 170 . 172 . 174 . 176 and inflow column 171 . 173 . 175 again arranged concentrically. The concrete form of the bridges 130 . 132 . 134 . 136 varies however. In particular, the webs 130 . 132 . 134 . 136 different lengths to the different distances of the outer edge 144 to the center M Take into account. Also, the webs 130 . 132 . 134 . 136 here different angles α on. But this does not have to be this way. Furthermore, here the solid filter 160 on the outer edge 144 be provided. Further flow guide elements 192 . 194 can be inside the proximal area 150 be provided.

The 5 shows a further embodiment of the storage pot bottom disclosed here 100 , Hereinafter, only the differences from the previous embodiments according to the 1 to 4 explained. The flow guide elements 170 . 172 . 174 . 176 are not convex here, but concave. At the same time, they could have no curvature. Compared to the previous embodiments according to the 1 to 4 are the flow guide elements 170 . 172 . 174 . 176 here further from the jetties 130 . 132 . 134 . 136 spaced. Furthermore, here is the jetty 134 as well as another bridge in the middle area bulbous designed, the better the equipment in the proximal area 150 to lead.

"Radially oriented" in this context means that the central axes of the channels or of the webs essentially run from the center of the storage pot bottom to the outer edge, whereby small deviations that are unimportant for the purposes intended here should be disregarded.

For the sake of legibility, the term "at least one" has been omitted for simplicity. If a feature of the technology disclosed herein is described in the singular or indefinite (eg, the / an inlet, the / a pipe, the / a web, the / a channel, the / a flow guide, etc.) so should also their Be disclosed with plurality (eg, the at least one inlet, the at least one pipe, the at least one web, the at least one channel, the at least one flow guide, etc.).

The term "substantially" (eg, "substantially vertical axis") in the context of the technology disclosed herein includes the exact property or the exact value (eg, "vertical axis") and deviations insignificant for the function of the property of the value ( eg "tolerable deviation from vertical axis").

The foregoing description of the present invention is for illustrative purposes only, and not for the purpose of limiting the invention. Various changes and modifications are possible within the scope of the invention without departing from the scope of the invention and its equivalents.

Claims (15)

Storage cup bottom (100) of a storage cup, comprising: - At least one inlet (110) for the flow of resources into the storage tank; - Several radially oriented channels (131, 133, 135) for transporting resources; wherein the channels (131, 133, 135) are each tapered from the peripheral area to the center of the storage pot bottom (100). Storage tank bottom (100) after Claim 1 wherein the channels (131, 133, 135) are formed on the storage pot bottom (100) such that at least 25% or at least 50% or at least 75% of the kinetic energy of static fluid flowing into the channels (131, 133, 135) is static is converted. Storage tank bottom (100) after Claim 1 or 2 wherein the channels (131, 133, 135) are each formed by two adjacent webs (130, 132, 132, 134, 134, 136). Storage tank bottom (100) after Claim 3 wherein the webs (130, 132, 134, 136) are substantially U-shaped or V-shaped, and wherein the central axes of the webs (130, 132, 134, 136) are radially oriented. Storage tank bottom (100) after Claim 3 or 4 , further the two ends of at least one web (130, 132, 134, 136) arranged further inside are as a central area of the same land (130, 132, 134, 136). Storage well bottom (100) according to any one of the preceding claims, wherein the webs (130, 132, 134, 136) and / or the channels (131, 133, 135) in a distal with respect to the center (M) of the storage cup bottom (100) Start region (140) and open in a with respect to the midpoint (M) of the storage pot bottom (100) proximal region (150). Storage tank bottom (100) after Claim 6 wherein the distal region (140) is an area at least 0.35D or at least 0.4D or at least 0.45D away from the midpoint (M) of the reservoir cup bottom (100); and wherein D is the distance between two opposite outer side regions of the reservoir cup bottom (100). Storage tank bottom (100) after Claim 6 or 7 wherein the proximal region (150) is an area that terminates at most 0.25D or at most 0.2D or at most 0.15D away from the midpoint (M) of the reservoir cup bottom (100); and wherein D is the distance between two opposite outer side regions of the reservoir cup bottom (100). Storage cup bottom (100) after one of the previous ones Claims 5 to 8th wherein the central areas are the direction reversal areas of the lands (130, 132, 134, 136) disposed immediately adjacent an outer edge (144). Storage well bottom (100) according to one of the preceding claims, wherein the channels (131, 133, 135) are arranged such that in all substantially from all directions on the storage pot bottom (100) incident equipment in the channels (131, 133, 135) can flow without having to flow around more than a quarter or a fifth of the outer peripheral surface of the storage pot bottom. Storage cup bottom (100) according to one of the preceding claims, wherein the inlet (110) from the center (M) of the storage cup bottom (100) is arranged spaced. Storage well bottom (100) according to one of the preceding claims, wherein the storage tank bottom (100) comprises at least one flow guide (170, 172, 174, 176) arranged to redirect resources emerging from a channel of the channels (131, 133, 135). Storage tank bottom (100) after Claim 12 wherein the at least one flow guide element (170, 172, 174, 176) is arranged, the operating means flowing out of one channel of the channels (131, 133, 135) at least partially into inner regions (I) of those adjacent webs (130, 132; 132, 134; 134, 136) which form this channel (131, 133, 135). Storage cup bottom (100) after one of the previous ones Claims 13 or 14 , wherein at least one inflow gap (171, 173, 175) is provided, which is formed by two flow guide elements (170, 172, 174, 176), wherein the inflow gap (171, 173, 175) is formed such that through the inflow (171, 173, 175) through the at least one flow guide (170, 172, 174, 176) diverted resource to the center (M) can flow. Storage cup bottom (100) according to one of the preceding claims, wherein the ends of the webs (130, 132, 134, 136) concentric with the center (M) of the storage cup bottom (100) are formed; and / or wherein the ends of the webs (130, 132, 134, 136) are formed immediately adjacent to the ends of the flow directors (170, 172, 174, 176).

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