FERMENTATION TANK

Abstract

A fermentation tank includes a tank body, enclosing a cavity therein, having a material inlet and a material outlet; a heat exchange structure, disposed on a wall of the cavity for heat exchanging with the tank body; at least one flow disturbing plate, being an elongated plate, the width direction of the flow disturbing plate being parallel to a radial direction of the tank body, the longitudinal direction of the flow disturbing plate being parallel to a vertical direction, a length of the flow disturbing plate being larger than a width thereof, the flow disturbing plate being arranged in the cavity and connected to the tank body, the flow disturbing plate having a heat exchange channel therein, two ends of the heat exchange channel communicating an exterior respectively so that heat is exchanged between the at least one flow disturbing plate and the cavity.

Claims

1. A fermentation tank, characterized by including: a tank body, having a top end and a bottom end and enclosing a cavity therein, a vertical direction being defined from a line composed of the top end and the bottom end, the tank body having a material inlet and a material outlet; a heat exchange structure, disposed on a wall of the cavity for heat exchanging with the tank body; at least one flow disturbing plate, the at least one flow disturbing plate being an elongated plate and having a width direction, a longitudinal direction, and a thickness direction which are perpendicular to each other, the width direction being parallel to a radial direction of the tank body, the longitudinal direction being parallel to the vertical direction, a length of the at least one flow disturbing plate being larger than a width thereof, the at least flow disturbing plate being arranged in the cavity and being connected to the tank body, the at least one flow disturbing plate having a heat exchange channel therein, two ends of the heat exchange channel communicating an exterior respectively so that heat is exchanged between the at least one flow disturbing plate and the cavity; wherein each of the at least one flow disturbing plate is a tubular member and in communication with the cavity of the tank body with two ends thereof, each of the at least one flow disturbing plate includes two side plate members and a bottom plate member connected between the two side plate members, and the bottom plate member is detachably connected to the tank body; wherein each of the at least one flow disturbing plate further includes a plurality of grooves and a plurality of ribs disposed at least on an inner surface thereof.

2. The fermentation tank of claim 1, wherein the heat exchange structure includes an exterior pipe, the exterior pipe extends as helix around an outer surface of the tank body, adjacent turns of the exterior pipe is spacedly arranged to form a gap therebetween, the exterior pipe has a first inlet and a first outlet, the first inlet and the first outlet communicate the exterior respectively.

3. The fermentation tank of claim 2, wherein the first inlet is located at a top of the exterior pipe, the first outlet is located at a bottom of the exterior pipe.

4. The fermentation tank of claim 2, wherein the first inlet is located at a bottom of the exterior pipe, the first outlet is located at a top of the exterior pipe.

5. The fermentation tank of claim 2, wherein the heat exchange structure further includes an interior pipe, the interior pipe extends as helix around an inner surface of the tank body, the interior pipe positionally corresponds to the gaps of the exterior pipe, the interior pipe has a second inlet and a second outlet, the second inlet and the second outlet communicate the exterior respectively.

6. The fermentation tank of claim 1, wherein the heat exchange channel extends the longitudinal direction and has a third inlet and a third outlet, the third inlet and the third outlet communicate the exterior respectively.

7. The fermentation tank of claim 6, wherein the heat exchange channel extends in a meandering way in the at least one flow disturbing plate, the third inlet is located at a bottom of the heat exchange channel, the third outlet is located at a top of the heat exchange channel.

8. The fermentation tank of claim 1, wherein the at least one flow disturbing plate includes at least four flow disturbing plates.

9. The fermentation tank of claim 1, wherein a stirring member is arranged in the tank body to stir fermentation material in the cavity.

10. The fermentation tank of claim 1, wherein the plurality of grooves and the plurality of ribs are disposed at least on the two side plate members.

11. The fermentation tank of claim 10, wherein the plurality of grooves and the plurality of ribs are alternatively arranged on either of the two side plate members.

12. The fermentation tank of claim 10, wherein the plurality of grooves includes a plurality of V-shaped grooves.

13. The fermentation tank of claim 12, wherein the plurality of grooves further includes a plurality of longitudinal grooves extending along the longitudinal direction and in communication with respective ends of the plurality of V-shaped grooves.

14. The fermentation tank of claim 12, wherein the plurality of grooves further includes a plurality of trapezoid grooves arranged at two edges of each of the two side plate members which extend in the longitudinal direction.

15. The fermentation tank of claim 10, wherein the plurality of ribs includes a plurality of V-shaped ribs.

16. The fermentation tank of claim 15, wherein the plurality of ribs further includes a plurality of longitudinal ribs extending along the longitudinal direction and connected with respective ends of the plurality of V-shaped ribs.

17. The fermentation tank of claim 15, wherein the plurality of ribs further includes a plurality of lateral ribs arranged at two edges of each of the two side plate members which extend in the longitudinal direction, and the plurality of lateral ribs extend in the width direction.

18. The fermentation tank of claim 10, wherein the plurality of grooves and the plurality of ribs are alternatively arranged on either of the two side plate members; the plurality of grooves includes a plurality of V-shaped grooves; the plurality of grooves further includes a plurality of longitudinal grooves extending along the longitudinal direction and in communication with respective ends of the plurality of V-shaped grooves; the plurality of grooves further includes a plurality of trapezoid grooves arranged at two edges of each of the two side plate members which extend in the longitudinal direction; the plurality of ribs includes a plurality of V-shaped ribs; the plurality of ribs includes a plurality of longitudinal ribs extending along the longitudinal direction and connected with respective ends of the plurality of V-shaped ribs; the plurality of ribs further includes a plurality of lateral ribs arranged on the two edges of each of the two side plate members which extend in the longitudinal direction, and the plurality of lateral ribs extend in the width direction; the plurality of longitudinal grooves are located between the respective ends of the plurality of V-shaped ribs and the plurality of lateral ribs.

19. The fermentation tank of claim 1, wherein the tank body further includes at least one connector, and each of the at least one flow disturbing plate further includes at least one connector which is connected with the bottom plate member and detachably connected with the at least one connector of the tank body.

20. The fermentation tank of claim 19, wherein the at least one connector of the at least one flow disturbing plate is inserted within the at least one connector of the tank body, and a fastening assembly is disposed through and secures the at least one connector of the tank body and the at least one connector of the at least one flow disturbing plate.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0010] FIG. 1 is a stereogram of the present invention;

[0011] FIG. 2 is a profile of the present invention;

[0012] FIG. 3A is a profile showing a flow disturbing plate of a second embodiment of the present invention;

[0013] FIG. 3B is a profile showing a flow disturbing plate of a third embodiment of the present invention;

[0014] FIG. 4 is a profile of the present invention at another angle;

[0015] FIG. 5 is a stereogram of an alternative embodiment of the present invention;

[0016] FIG. 6 is a cross-sectional view of FIG. 5;

[0017] FIG. 7 is another cross-sectional view of FIG. 5;

[0018] FIG. 8 is an enlargement of FIG. 7; and

[0019] FIG. 9 is an enlargement of a flow disturbing plate of the alternative embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

[0020] Please refer to FIG. 1 to FIG. 4, the fermentation tank of the present invention includes a tank body 10, a heat exchange structure, and at least one flow disturbing plate 30.

[0021] The tank body 10 has a top end and a bottom end and encloses a cavity 11 therein. A vertical direction is defined from a line composed of the top end and the bottom end. The tank body 10 has a material inlet 12 and a material outlet 13. The heat exchange structure is disposed on a wall of the cavity 11 for heat exchanging with the tank body 10. The at least one flow disturbing plate 30 is an elongated plate and has a width direction, a longitudinal direction, and a thickness direction which are perpendicular to each other. The width direction is parallel to a radial direction of the tank body 10. The longitudinal direction is parallel to the vertical direction. A length of the at least one flow disturbing plate 30 is larger than a width thereof. The at least flow disturbing plate 30 is arranged in the cavity 11 and is connected to the tank body 10. The at least one flow disturbing plate 30 has a heat exchange channel 31 therein. (The heat exchange channel can be directly formed in the hollow flow disturbing plate.) Two ends of the heat exchange channel 31 communicate an exterior respectively so that heat is exchanged between the at least one flow disturbing plate 30 and the cavity 11. In the present embodiment, four flow disturbing plate 30 are included and arranged spacedly.

[0022] In the present embodiment, the heat exchange structure includes an exterior pipe 21. The exterior pipe 21 extends as helix around the outer surface of the tank body 10. Any adjacent turns of the exterior pipe 21 are spacedly arranged to form a gap. The exterior pipe 21 has a first inlet 211 and a first outlet 212. The first inlet 211 and the first outlet 212 communicate the exterior respectively. Preferably, the heat exchange structure further includes an interior pipe 22. The interior pipe 22 extends as helix around the inner wall of the tank body 10. The interior pipe 22 positionally corresponds to the gaps of the exterior pipe 21. The interior pipe 22 has a second inlet 221 and a second outlet 222. The second inlet 221 and the second outlet 222 communicate the exterior respectively. Specifically, the first inlet is located at the top of the exterior pipe, and the first outlet is located at the bottom of the exterior pipe. However, in other possible embodiments, the first inlet can be located at the bottom of the exterior pipe, and the first outlet can be located at the top of the exterior pipe.

[0023] More specifically, the heat exchange channel 31 extends along the longitudinal direction and has a third outlet 311 and the third inlet 312 communicating the exterior respectively. The third outlet 311 is located at the top of the heat exchange channel 31, and the third inlet 312 is located at the bottom of the heat exchange channel 31.

[0024] In other possible embodiments, the flow disturbing plate 30 has plural horizontal plates arranged staggered to enclose the meandering heat exchange channel 31a, as shown in FIG. 3A. Or the heat exchange channel 31b can be a meandering or helix pipe received in the flow disturbing plate 30.

[0025] Optionally, the tank body 10 has a stirring member 14 therein to stir the fermentation material in the cavity 11.

[0026] In the present embodiment, the first inlet 211, the second inlet 221, and the third inlet 312 are independent to each other, and the first outlet 212, the second outlet 222, and the third outlet 311 are also independent to each other. However, in other possible embodiments, the first inlet 211, the second inlet 221, and the third inlet 312 can converge into a same inlet, and the first outlet 212, the second outlet 222, and the third outlet 311 can also converge into a same outlet. Besides, the third inlets 312 of the plural flow disturbing plates 30 can converge into a same inlet, the third outlets 311 can also converge into a same outlet.

[0027] In an alternative embodiment as shown in FIG. 5 to FIG. 9, each of the at least one flow disturbing plate 40 is a tubular member (rectangular, circular or in other shapes) and in communication with the cavity 11 of the tank body 10 with two ends thereof, each of the at least one flow disturbing plate 40 includes two side plate members 41 and a bottom plate member 42 connected between the two side plate members 41, and the bottom plate member 42 is detachably connected to the tank body 10. The tank body 10 further includes at least one connector 15, and each of the at least one flow disturbing plate 40 further includes at least one connector 44 which is connected with the bottom plate member 42 and detachably connected with the at least one connector 15 of the tank body 10, which is easy to assemble/disassemble and replace. The bottom plate member 42 may be connected with the two side plate members 41 by welding or the like or may be integrally formed with the two side plate members 41 of one piece. The at least one connector 44 may be connected with the bottom plate member 42 by welding or the like or may be integrally formed with the bottom plate member 42 of one piece. The at least one connector 44 of the at least one flow disturbing plate 40 is inserted within the at least one connector 15 of the tank body 10, and a fastening assembly 50 (such as bolt and nut) is disposed through and secures the at least one connector 15 of the tank body 10 and the at least one connector 44 of the at least one flow disturbing plate 40. Each of the at least one flow disturbing plate 40 further includes a plurality of grooves 45 and a plurality of ribs 46 disposed at least on an inner surface thereof. Specifically, the plurality of grooves 45 and the plurality of ribs 46 are disposed at least on the two side plate members 41. The plurality of grooves 45 and the plurality of ribs 46 are alternatively arranged on either of the two side plate members 41. The plurality of grooves 45 includes a plurality of V-shaped grooves 451. The plurality of grooves 45 further includes a plurality of longitudinal grooves 452 extending along the longitudinal direction and in communication with respective ends of the plurality of V-shaped grooves 451. The plurality of grooves 45 further includes a plurality of trapezoid grooves 453 arranged at two edges of each of the two side plate members 41 which extend in the longitudinal direction. The plurality of ribs 46 includes a plurality of V-shaped ribs 461. The plurality of ribs 46 further includes a plurality of longitudinal ribs 462 which extend along the longitudinal direction and connected with respective ends of the plurality of V-shaped ribs 461. The plurality of ribs 46 further includes a plurality of lateral ribs 463 arranged on the two edges of each of the two side plate members which extend in the longitudinal direction, and the plurality of lateral ribs 463 extend in the width direction. The plurality of longitudinal grooves 452 are located between the respective ends of the plurality of V-shaped ribs 461 and the plurality of lateral ribs 463. The plurality of ribs 46 enforce the structural strength of the at least one flow disturbing plate 40, and the plurality of grooves 45 and the plurality of ribs 46 improve the flow disturbing and efficiency of heat exchanging.

[0028] In use, the exterior pipe, the interior pipe, and the heat exchange channel are adapted for steam, hot water, or others to pass through for heating. Because the gaps of the exterior pipe don't contribute to the heating, the interior pipe can make up for it. Thus, the whole wall of the tank body can be heated evenly. In addition, the conventional flow disturbing plates are disposed with heat exchange channels, so the efficiency of heating is improved.

[0029] Besides, the interior pipe disposed on the inner wall of the tank body is easy to wash.

[0030] In conclusion, the fermentation tank has improved efficiency of heat exchanging, and the heat exchange is even. In addition, the heating device may not occupy too much space of the cavity. Furthermore, the fermentation tank is easy to wash.