Center of mass control of liquid tanks for spacecraft use

Abstract

A rigid structure propellant management device (PMD) liquid storage tank includes an outer shell and internal structures inside the outer shell that include a plurality of vertical columns each made up of a stack of individual storage cells. Each of the storage cells has solid vertical sidewalls and top and bottom capillary windows that allow vertical liquid transfer between adjacent cells in a vertical column. The top and bottom capillary windows in each of the storage cells have permeabilities that result in a selected direction of liquid flow in each column. A piping and valve system may be connected to the top capillary window of a top storage cell and to the bottom capillary window of a bottom storage cell of each vertical column, configured to allow controlled liquid transfer between adjacent vertical columns so that locations of empty cells in the tank as liquid is drawn from the tank achieves a selected column by column drainage sequence and controls a center of mass of the tank.

Claims

1. A rigid structure propellant management device (PMD) liquid storage tank comprising: an outer shell; internal structures inside the outer shell comprising a plurality of vertical columns each comprising a stack of individual storage cells, wherein each of the storage cells comprises solid vertical sidewalls and top and bottom capillary windows that allow vertical liquid transfer between adjacent cells in a vertical column, the top and bottom capillary windows in each of the storage cells having permeabilities that result in a selected direction of liquid flow in each column; and a piping and valve system connected to the top capillary window of a top storage cell and to the bottom capillary window of a bottom storage cell of each vertical column, the piping and valve system being configured to allow controlled liquid transfer between adjacent vertical columns; wherein the piping and valve system, and the top capillary window of the top storage cell and the bottom capillary window of the bottom storage cell of each vertical column, are configured and arranged to control locations of empty cells in the tank as liquid is drawn from the tank to achieve a selected column by column drainage sequence and to control a center of mass of the tank.

2. The rigid structure PMD liquid storage tank of claim 1, wherein the outer shell and internal structures are metal or plastic structures.

3. The rigid structure PMD liquid storage tank of claim 1, wherein the capillary windows comprise woven screens or holes that are capillary wetted by the liquid.

4. The rigid structure PMD liquid storage tank of claim 1, wherein the vertical columns of storage cells have separate walls.

5. The rigid structure PMD liquid storage tank of claim 1, wherein the vertical columns of storage cells share a common wall.

6. The rigid structure PMD liquid storage tank of claim 1, wherein the storage cells in each vertical column have cross-sectional shapes that are circular, hexagonal, or truncated circular sectors.

7. The rigid structure PMD liquid storage tank of claim 1, wherein the vertical columns of storage cells are supported by a plurality of bulkheads that are attached to the outer shell of the storage tank.

8. A method of producing a rigid structure propellant management device (PMD) liquid storage tank for storing liquid in a microgravity environment, the method comprising: forming the tank with an outer shell and internal structures inside the outer shell comprising a plurality of vertical columns of storage cells, each of the storage cells comprising vertical sidewalls and top and bottom capillary windows that allow vertical liquid transfer between adjacent cells in each of the vertical columns; forming the top and bottom capillary windows in each of the storage cells wit permeabilities that result in a selected direction of liquid flow through the storage cells in each of the vertical columns; providing a piping and valve system connected to the top capillary window of a top storage cell and to the bottom capillary window of a bottom storage cell of each vertical column, the piping and valve system being configured to allow controlled liquid transfer between adjacent vertical columns; and configuring the piping and valve system, and the top capillary window of the top storage cell and the bottom capillary window of the bottom storage cell of each vertical column, to control locations of empty cells in the tank as liquid is drawn from the tank to achieve a selected column by column drainage sequence and to control a center of mass of the tank.

9. The method of claim 8, wherein the outer shell and internal structures are metallic or plastic structures.

10. The method of claim 8, wherein the capillary windows comprise woven screens or holes that are capillary wetted by the liquid.

11. The method of claim 8, wherein the vertical columns of storage cells have separate walls.

12. The method of claim 8, wherein the vertical columns of storage cells share a common wall.

13. The method of claim 8, wherein the storage cells in each vertical column have cross- sectional shapes that are circular, hexagonal, or truncated circular sectors.

14. The method of claim 8, wherein the vertical columns of storage cells are supported by a plurality of bulkheads that are attached to the outer shell of the storage tank.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1A is a schematic illustration of a rigid structure PMD with a ullage bubble.

(2) FIG. 1B is a schematic illustration of the PMD of FIG. 1A after an acceleration.

(3) FIG. 2A is a schematic illustration of a rigid structure PMD with internal subdivisions and a ullage bubble.

(4) FIG. 2B is a schematic illustration of the PMD of FIG. 2A after an acceleration.

(5) FIG. 3 is a schematic illustration of a rigid structure PMD with internal compartments separated by capillary windows.

(6) FIG. 4 is a cut away view of a rigid structure PMD with internal compartments, capillary windows, and baffles.

(7) FIG. 5 is a schematic illustration of a rigid structure PMD with interconnected vertically stacked internal compartments.

(8) FIG. 6 is a schematic cross-section of a rigid structure PMD with individual storage columns with different shapes.

(9) FIG. 7 is a schematic illustration of a rigid structure PMD with vertically stacked internal compartments with a controlled center of mass.

(10) FIG. 8 is a cut away view of a rigid structure PMD with multiple storage compartments, capillary windows, and inter-column fluid control.

DETAILED DESCRIPTION

(11) FIG. 1A illustrates the movement of liquid within a traditional rigid structure PMD 10. PMD 10 comprises tank wall 12, liquid propellant 14, and ullage gas bubble 16. For example, ullage bubble 16 may be located towards the bottom of the tank when in microgravity. If the tank is accelerated toward the upper right, the ullage bubble drifts to the right and top causing a significant shift in the center of mass as shown in FIG. 1B. However, if the tank is subdivided as shown in FIG. 2A into cells divided by barriers 28, the center of mass moves significantly less as shown in FIG. 2B.

(12) As shown above, a rigid structure PMD may be capable of restricting the center of mass movement. In principle, if small cells containing liquid are drained sequentially such that only one cell or a limited number of cells are partially filled and the rest are nearly filled or empty, only a small amount of liquid may move thereby restricting the center of mass movement. One concept PMD comprises an outer tank with internal cells that restrict the center of mass movement (CoM cells) that contain the remaining liquid and appropriate support structures for the CoM cells. This concept is illustrated by PMD structure 30 in FIG. 3. PMD structure 30 comprises outer tank shell 32, CoM cells 34, capillary windows 36, and storage compartments 38 and 39 above and below the capillary windows. Storage compartments 38 may be a region where ullage gas to pressure the tank may be stored. Storage compartment 39 may contain traditional PMD structures to collect propellant or move propellant to a tank outlet.

(13) Capillary windows 36 may consist of tightly woven screens or small holes that are capillary wetted by liquid. These structures may significantly reduce gas from entering adjacent full compartments or liquid from entering prior adjacent dry compartments.

(14) An improved system and method of controlling and restricting the center of mass movement using a rigid structure PMD, wherein each single CoM cell has internal structures in addition to the capillary windows on the bottom and top of the cells, is described in detail below. FIG. 4 shows a cut away view of rigid PMD structure 40, which is configured such that each single CoM cell has internal structures in addition to the capillary windows on the bottom and top of the cells. Rigid PMD structure 40 comprises tank shell 42, upper dome 43, vertical cell walls 44, lower dome 45, capillary window 46, upper tank connection 47, and lower tank connection 48. The vertical cell walls (or baffles) 44 segment the liquid into different cells 49. This further reduces the lateral center of mass movement by reducing the distance and rate the fluid can travel within the storage tank. In various embodiments, the baffles may or may not permit fluid communication between cells as required based on anticipated acceleration in the mission profile. This fluid movement does not significantly affect the performance of this concept because an entire cell is drained via the capillary windows to the next cell. The baffles may be arranged in a variety of ways in any compartmental shape.

(15) In another embodiment, as illustrated in FIG. 5, multiple vertical columns of CoM cells may be arranged to manage the center of mass control. FIG. 5 shows a schematic illustration of rigid structure PMD 50 with interconnected vertical columns comprising tank shell 52, top barrier 53, vertical baffle 54, bottom barrier 55, capillary window 56, piping 57, upper storage chamber 58, and lower storage chamber 59. In embodiments using multiple columns, such as shown in FIG. 5, each column of CoM cells is similar to the single column concept described above. Each cell provides liquid from an upper cell to a lower cell using capillary windows. At the bottom of a column, liquid is scavenged and piped to the next column. The pipe may lead to the bottom or top of the next column (the use of the terms such as pipe, top, bottom, upper, and lower are to assist the reader in visualizing flow based on the sketches.) The actual communication device and direction of flow within each column is based on the design and placement of wicking and storage structures and not related to orientation to Earth or other gravitational forces. The columns may be parallel as shown or mutually perpendicular along all three Cartesian coordinates or in other configurations. The last CoM cell may feed directly into the tank outlet, as shown in FIG. 5 or empty into storage chamber 59 below the CoM cells. In the latter, a traditional PMD is used to collect the liquid to supply the tank outlet. These multiple columns of CoM cells are typically supported by two or more bulkheads that are attached to the shell of the tank.

(16) Columns of CoM cells can have various shapes and can be arranged different ways. FIGS. 6A, 6B, and 6C show three possible arrangements, but other arrangements and shapes are possible. For example, the individual compartments may be comprised of circular (FIG. 6A), hexagonal (FIG. 6B), truncated circular sectors (FIG. 6C) or other cross-sectional shapes. Individual columns may have separate walls (as shown in the walls 62 of circular columns in FIG. 6A) or share a common wall (as illustrated in the walls 64 of hexagonal columns in FIG. 6B, and in the walls 66 of truncated circular sectors in FIG. 6C). The regions within the tank void of the CoM cells are used to route piping and provide a region for pressurent gas. By arranging the cells and their draining sequence the center of mass for the tank and its contents may be optimized. For example, in the sequencing arrangement depicted in FIG. 5, transient lateral shifts in center of mass are substantially controlled during position and orientation maneuvers of the spacecraft, but the center of mass of the tank and its contents shift as fuel is removed from the tank.

(17) FIG. 7 is a schematic illustration of rigid PMD structure 70 configured so that the flow arrangement can be controlled to maintain the center of mass constant as fuel is consumed. As shown in FIG. 7, rigid PMD structure 70 has four vertical columns wherein the fourth column is behind the center column in the figure. Rigid PMD structure 70 has four interconnected vertical columns comprising tank shell 72, top barrier 73, vertical baffles 74, bottom barrier 75, capillary windows 76, piping 77, upper storage chamber 78, and lower storage chamber 79. A left vertical column is indicated by arrow L. A right vertical column is indicated by arrow R. A front vertical column is indicated arrow F and a back vertical column that is not visible in the figure is indicated by dotted arrow B. The bubble point gradients in each column are set such that the top CoM cells of the right and left columns empty from the top down and the front and back center columns empty from the bottom up thereby leaving the center of mass unchanged. Bubble point is defined as the pressure required to blow the first continuous bubbles detectable through a sample.

(18) FIG. 8 is a cut away view of rigid PMD structure 80 with multiple vertical columns of CoM storage cells. PMD structure 80 comprises tank shell 82, top barrier 83, vertical barrier 84, bottom barrier 85, capillary window 86, piping 87, upper storage chamber 88, lower storage chamber 89, upper tank connection 90 and lower tank connection 92. Capillary windows 86 that comprise the entry and exit points for each CoM cell use screens (woven screens or plates with a field of small holes) to readily pass fluid between compartments, but will block gas flow until the differential pressure across the screen exceeds the bubble point of the screen. In the vertical columns of the invention, capillary windows with varying bubble points can pass fluid through a column from one level in the column at a time. This will enable the propellant tank to substantially maintain its center of mass as fuel is consumed during a mission. In FIG. 8 the direction of fluid flow is indicated by arrow A.

(19) While the invention has been described with reference to an exemplary embodiment(s), it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope of the invention. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the invention without departing from the essential scope thereof. Therefore, it is intended that the invention not be limited to the particular embodiment(s) disclosed, but that the invention will include all embodiments falling within the scope of the appended claims.