Insert for evaporator header

Abstract

Disclosed is an evaporator header insert, including: a header insert body that extends along a body center axis between body inlet and outlet ends, a center passage located within the header insert body, the center passage extending from the body inlet end to the body outlet end along the body center axis, the center passage surface defining: a center passage inlet portion at the body inlet end; a center passage outlet portion, at the body outlet end, that defines a body nozzle portion on the body center axis, wherein the body nozzle portion has a convergent-divergent shape so that the body nozzle portion has a convergent segment, a divergent segment and a neck segment therebetween; and a conical tip member, fixed to the body outlet end and disposed at least partially within the divergent segment of the body nozzle portion so that a conical outlet passage is formed therebetween.

Claims

1. A header insert for an evaporator header outlet port of an evaporator header, comprising: a header insert body that extends along a body center axis between a body inlet end and a body outlet end, a flange that extends radially outwardly from the header insert from a location that is axially between the body inlet end and the body outlet end; wherein the header insert body includes a center passage defined by a center passage surface located within the header insert body, the center passage surface extending from the body inlet end to the body outlet end along the body center axis, the center passage surface defining: a center passage inlet portion at the body inlet end; a center passage outlet portion at the body outlet end, the center passage outlet portion defining: a body nozzle portion on the body center axis, the body nozzle portion having a convergent-divergent shape so that the body nozzle portion has: a convergent segment located between the flange and the body outlet end, wherein a center passage diameter of the center passage is constant between the body inlet and the convergent segment; a divergent segment extending from the convergent section to the body outlet end to define an axial outer edge of the body outlet end; and a neck segment therebetween; and a conical tip member, fixed to the body outlet end and disposed at least partially within the divergent segment of the body nozzle portion so that a conical outlet passage is formed therebetween, a conical tip member base portion is defined by the conical tip member, the conical tip base member located at the axial outer edge of the body outlet end.

2. The header insert of claim 1, wherein: a divergent segment diameter is defined by the divergent segment, the divergent segment diameter sized so that the divergent segment defines the axial outer edge of the body outlet end.

3. The header insert of claim 2, wherein: the conical tip member base portion has a base portion diameter that is larger than a center passage diameter; and the base portion diameter of the conical tip member is smaller than the divergent segment diameter.

4. The header insert of claim 1, further comprising: one or more runners that connect the conical tip member to the body outlet end.

5. An evaporator assembly including the header insert of claim 1, and further comprising: the evaporator header that defines the evaporator header outlet port; an evaporator body that defines an evaporator passage in fluid communication with the evaporator header outlet port, and wherein the header insert is inserted into the evaporator header outlet port.

6. A method of directing fluid through an evaporator assembly, comprising: directing a fluid into a center passage inlet portion of the center passage surface of the header insert of claim 1 from the evaporator header outlet port of the evaporator header; directing the fluid into the center passage outlet portion at the body outlet end of the center passage surface, the center passage outlet portion defining the body nozzle portion on the body center axis, the body nozzle portion having the convergent-divergent shape so that the body nozzle portion has the convergent segment, the divergent segment and the neck segment therebetween; directing the fluid into the conical outlet passage formed between the divergent segment of the body nozzle portion and the conical tip member fixed to the body outlet end of the header insert; and directing the fluid into an evaporator passage of an evaporator body from the conical outlet passage, wherein the fluid moves towards a sidewall of the evaporator passage and moves downstream along the evaporator passage.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) The present disclosure is illustrated by way of example and not limited in the accompanying figures in which like reference numerals indicate similar elements.

(2) FIG. 1 is an isometric view of a prior art insert for an evaporator;

(3) FIG. 2 is a cross sectional view of an evaporator equipped with the insert of FIG. 1;

(4) FIG. 3 is an isometric view of an evaporator header insert according to an embodiment;

(5) FIG. 4 is a cross-sectional view of the evaporator header insert of FIG. 3 taken along lines A-A in FIG. 3, according to an embodiment;

(6) FIGS. 5 and 6 are cross sectional views of an evaporator equipped with the evaporator header insert of FIG. 3;

(7) FIG. 7 is a flowchart showing a method of evaporating a single-phase liquid or two-phase fluid with an evaporator assembly;

(8) FIG. 8 is an isometric view of an insert assembly according to an embodiment;

(9) FIG. 9 is an exploded view of the insert assembly of FIG. 8, with an evaporator header insert of the insert assembly shown in cross-section along lines B-B in FIG. 8, according to an embodiment;

(10) FIGS. 10 and 11 are cross sectional views of an evaporator equipped with the insert assembly of FIG. 8; and

(11) FIG. 12 is a flowchart showing another method of evaporating a single-phase liquid or two-phase fluid with an evaporator assembly.

DETAILED DESCRIPTION

(12) Aspects of the disclosed embodiments will now be addressed with reference to the figures. Aspects in any one figure is equally applicable to any other figure unless otherwise indicated. Aspects illustrated in the figures are for purposes of supporting the disclosure and are not in any way intended on limiting the scope of the disclosed embodiments. Any sequence of numbering in the figures is for reference purposes only.

(13) As indicated, in a parallel flow passage design, under adverse gravity conditions, characteristics of the flow dynamics into the evaporator passages from the header may result in reduced contact between the working fluid and the evaporator, which may reduce effectiveness of the system. As shown in FIGS. 1 and 2, a prior art evaporator assembly 55 (FIG. 2) typically includes a plurality of inserts generally referred to as 50 (for simplicity, a single insert 50a is shown in FIGS. 1-2). The inserts 50 are disposed in respective ones of a plurality of outlet ports 70 (for simplicity, a single outlet port 70a is labeled in FIG. 2) of an evaporator header 60 (FIG. 2). An evaporator body 85 includes a plurality of evaporator passages generally referred to as 80 (for simplicity, a single evaporator passage 80a is labeled in FIG. 2). The evaporator passages 80 are generally parallel to one another in the evaporator body 85. Through the insert 50a, the outlet port 70a may fluidly communicate with the evaporator passage 80a. Heat energy 90 may be applied to either side or both sides of the evaporator body 85. To achieve uniform flow distribution in the parallel flow passages design, the insert 50a is commonly used to create desired back pressure at the entrance of the evaporator passage 80a.

(14) Flow lines 95 shown in FIG. 2 indicate the fluid flow direction through the insert-passage 62 and inside the evaporator passage 80a in a microgravity environment, such as in an aerospace application. Undisturbed fluid may flow mostly in a straight line without contacting a sidewall 100 of the evaporator passage 80a. In order to have an efficient operation, the fluid phase of the working fluid should contact the sidewall 100 of the evaporator passage 80a along an entire length of the evaporator passage 80a. Otherwise, available heat along the full length of the sidewall 100 may remain in the evaporator body 85. This is inefficient and may result in damage to the evaporator body 85.

(15) In view of the above identified concerns, turning to FIGS. 3-6, a header insert 200 for the evaporator header outlet port 70A is illustrated. The header insert 200 can be utilized in place of the known inserts 50 shown above in the header 60. The header insert 200 includes a header insert body 210 that extends along a body center axis 220, between a body inlet end 230 and a body outlet end 240.

(16) The header insert body 210 includes a center passage 250 defined by a center passage surface 260 located within the header insert body 210. The center passage surface 260 extends from the body inlet end 230 to the body outlet end 240 along the body center axis 220. The center passage surface 260 defines a center passage inlet portion 270 at the body inlet end 230.

(17) A center passage outlet portion 280 is at the body outlet end 240. The center passage outlet portion 280 defines a body nozzle portion 290 on the body center axis 220. The body nozzle portion 290 has a convergent-divergent shape, so that the body nozzle portion 290 has a convergent segment 300, a divergent segment 310A and a neck segment 320 therebetween.

(18) A conical tip member 330 is fixed to the body outlet end 240 and disposed at least partially within the divergent segment 310A, so that a conical outlet passage 340 is formed therebetween.

(19) A divergent segment diameter 350 is defined by the divergent segment 310A. The divergent segment diameter 350 extends to an axial outer edge 360 of the body outlet end 240. A conical tip member base portion 370 is defined by the conical tip member 330. The conical tip member base portion 370 has a base portion diameter 380 that is larger than a center passage diameter 390. The base portion diameter 380 of the conical tip member 330 is smaller than the divergent segment diameter 350. One or more runners 400 connects the conical tip member 330 to the body outlet end.

(20) A flange 410 extends radially outwardly from the header insert 200 from a location that is axially between the body inlet end 230 and the body outlet end 240. The center passage outlet portion 280 of the center passage surface 260 is axially between the flange 410 and the body outlet end 240.

(21) Tuning to FIGS. 5 and 6, the header insert 200 is disposed in the evaporator header outlet port 70A of the header insert 200. Flow out of the header insert 200 into the evaporator passage 80A of the evaporator body 85 flows against the sidewall 100 near the header insert 200. This improves transfer of the heat energy 90 with the evaporator passage 80A.

(22) FIG. 7 is a flowchart showing a method for directing fluid through the evaporator header 60. As shown in block 710, the method includes directing a fluid into the center passage inlet portion 270 of the center passage surface 260 of the header insert 200 from the evaporator header outlet port 70A of the evaporator header 60. As shown in block 720, the method includes directing the fluid into the center passage outlet portion 280 at the body outlet end 240 of the center passage surface 260. The center passage outlet portion 280 defines the body nozzle portion 290 on the body center axis 220. The body nozzle portion 290 has the convergent-divergent shape so that body nozzle portion 290 has the convergent segment 300, the divergent segment 310A and the neck segment 320 therebetween.

(23) As shown in block 730, the method further includes directing the fluid into the conical outlet passage 340 formed between the divergent segment 310A of the center passage outlet portion 280 and the conical tip member 330 fixed to the body outlet end 240 of the header insert 200. As shown in block 740, the method includes directing the fluid into the evaporator passage 80A of the evaporator body 85 from the conical outlet passage 340. In the evaporator body 85, the fluid moves towards the sidewall 100 of the evaporator passage 80A as the fluid moves downstream along the evaporator passage 80A.

(24) FIGS. 8-9 illustrate an embodiment where a header insert assembly 800 is provided. The assembly 800 includes a header insert 200A and an internal insert 500A. Terminology having reference numbers that are the same as those in the above disclosed embodiment shall be construed the same except as otherwise disclosed herein. The internal insert 510A extends along an internal insert body center axis 250A. The internal insert 510A defines an internal insert tip portion 530A, and an internal insert base portion 540A axially spaced therefrom. An internal insert center body portion 550A extends axially between the internal insert tip portion 530A and the internal insert base portion 540A.

(25) The internal insert tip portion 530A converges away from the internal insert center body portion 550A. The internal insert center body portion 550A defines a first axial segment 560A and a second axial segment 570A extending away from one another along the axis 520A. The first axial segment 560A extends to the internal insert tip portion 530A and the second axial segment 570A extends to the internal insert base portion 540A along the axis 520A.

(26) The first axial segment 560A of the internal insert center body portion 550A defines a first axial segment diameter 595A that is substantially constant. The second axial segment 570A of the internal insert center body portion 550A is formed to taper conically from the first axial segment 560A to the internal insert base portion 540A.

(27) A helical fluid passage surface 580A, defining a continuous helical fluid passage 590A, is formed into the internal insert center body portion 550A. A ring segment 600A is defined by the internal insert base portion 540A. The ring segment 600A has a ring segment outer dimeter 610A that is larger than the first axial segment diameter 595A.

(28) A plurality of ribs 615A (a rib 615A1 is labeled in FIG. 9) are formed by the internal insert base portion 540A. The plurality of ribs 615A are circumferentially spaced apart from one another and extend radially inwardly to connect the ring segment 600A and the internal insert 510A with one another. This configuration defines a plurality of fluid inlet ports 620A circumferentially spaced apart from one another. The plurality of fluid inlet ports 620A are configured to guide fluid therethrough toward the helical fluid passage surface 580A along the second axial segment 570A of the internal insert center body portion 550A.

(29) A first radial through-hole 630A is formed through the internal insert base portion 540A. The first radial through-hole 630A is configured to receive a fixing pin 640A (illustrated schematically) for fixing the internal insert 510A to the header insert 200A.

(30) The header insert 200A includes a header insert body 210A that extends along a body center axis 220A between a body inlet end 230A and a body outlet end 240A. The header insert body 210A includes a center passage surface 260A defining a center passage 250 that extends from the body inlet end 230A to the body outlet end 240A along the body center axis 220A. The center passage surface 260A defines a center passage inlet portion 270A at the body inlet end 230A. A center passage outlet portion 280A is defined by the center passage surface 260A at the body outlet end 240A. The center passage outlet portion 280A defines a body nozzle portion 290A on the body center axis 220A. The body nozzle portion 290A has a convergent-divergent shape so that the body nozzle portion 290A has a convergent segment 300A, a divergent segment 310A and a neck segment 320A therebetween.

(31) The internal insert 510A is configured for being disposed within the center passage 250. In this configuration, the internal insert tip portion 530A is disposed at the convergent segment 300A of the body nozzle portion 290A and the internal insert base portion 540A is at the center passage inlet portion 270A of the center passage surface 260A.

(32) A radial outward step 650A is formed at the body outlet end 240A of the header insert 200A. The radial outward step 650A is configured for seating against the internal insert base portion 540A. This configuration limits axial motion of the internal insert 510A within the header insert 200A.

(33) A second radial through-hole 660A is formed by the body outlet end 240A of the header insert 200A. When the internal insert 510A is within the header insert 200A, the first radial through-hole 630A in the internal insert 510A and the second radial through-hole 660A are aligned with one another and configured for receiving the fixing pin 640A.

(34) A length of the internal insert 510A, along the body center axis 220A, is substantially the same as a length of the center passage 250, between the body outlet end 240A and the neck segment 320A of the body nozzle portion 290A. In one embodiment the internal insert 510A is configured for a clearance fit within the center passage 250.

(35) Tuning to FIGS. 10 and 11, the header insert 200A is disposed in the evaporator header outlet port 70A of the header insert 200. Flow out of the header insert 200A into the evaporator passage 80A of the evaporator body 85 flows against the sidewall 100 near the header insert 200A. This improves transfer of the heat energy 90 with the evaporator passage 80A.

(36) FIG. 12 is a flowchart showing another method for directing fluid through the evaporator header 60. As shown in block 1210, the method includes directing the fluid along the center passage surface 260A of the header insert 200A from the evaporator header outlet port 70A of the evaporator header 60. As shown in block 1220, the method includes directing the fluid along the internal insert base portion 540A of the internal insert 510A disposed with the center passage 250. As shown in block 1230, the method includes directing the fluid along the helical fluid passage surface 580A formed into the internal insert center body portion 550A.

(37) As shown in block 1240, the method includes directing the fluid between the internal insert tip portion 530A and the convergent segment 300A of the nozzle portion 290A of the center passage surface 260A. As shown in block 1250, the method includes directing the fluid through the neck segment 320A of the nozzle portion 290A of the center passage surface 260A. As sown in block 1260, the method includes directing the fluid out of the divergent segment 310A of the nozzle portion 290A of the center passage surface 260A. As shown in block 1270, the method includes directing the fluid into the evaporator passage 80A of an evaporator body 85 from the center passage outlet portion 280A of the center passage surface 260A. From this, the fluid moves towards the sidewall 100 of the evaporator passage 80A as the fluid moves downstream along the evaporator passage 80A.

(38) In one embodiment, directing the fluid through the internal insert base portion 540A includes directing the fluid through a plurality of fluid inlet ports 620A circumferentially spaced apart from one another. The plurality of fluid inlet ports 620A are defined by the plurality of ribs 615A that are circumferentially spaced apart from one another and connect the ring segment 600A of the internal insert base portion 540A to the internal insert 510A.

(39) The terminology used herein is for the purpose of describing particular embodiments only and is not intended to be limiting of the present disclosure. As used herein, the singular forms “a”, “an” and “the” are intended to include the plural forms as well, unless the context clearly indicates otherwise. It will be further understood that the terms “comprises” and/or “comprising,” when used in this specification, specify the presence of stated features, integers, steps, operations, elements, and/or components, but do not preclude the presence or addition of one or more other features, integers, steps, operations, element components, and/or groups thereof.

(40) Those of skill in the art will appreciate that various example embodiments are shown and described herein, each having certain features in the particular embodiments, but the present disclosure is not thus limited. Rather, the present disclosure can be modified to incorporate any number of variations, alterations, substitutions, combinations, sub-combinations, or equivalent arrangements not heretofore described, but which are commensurate with the scope of the present disclosure. Additionally, while various embodiments of the present disclosure have been described, it is to be understood that aspects of the present disclosure may include only some of the described embodiments. Accordingly, the present disclosure is not to be seen as limited by the foregoing description, but is only limited by the scope of the appended claims.