CA2488000A1 - Vapor generator - Google Patents

Abstract

A vapor generator comprising an evaporator unit, which in turn includes an inner chamber for containing a first fluid in a liquid state, and further includes a preheated liquid inlet and a vapor outlet, the evaporator unit having a heating device therein which can be activated for vaporizing the first fluid contained in the inner chamber to generate vapor. The vapor generator further comprises a preheating tank defining an inner chamber and comprising a liquid inlet for injection of the first fluid in a liquid state in the inner chamber, and a liquid outlet. Moreover, the vapor generator comprises an opened liquid channel connecting the preheating tank liquid outlet to the evaporator unit liquid inlet, and establishing free and continuous fluid communication between the preheating tank inner chamber and the evaporator unit inner chamber. The first fluid in a liquid state injected through the preheating tank liquid inlet is continuously distributed between the evaporator unit inner chamber and the preheating tank inner chamber through the liquid channel. and the heating device of the evaporator unit can be activated for generating a temperature gradient across the liquid-state first fluid contained in the evaporator unit inner chamber. the liquid channel and the preheating tank inner chamber, the first fluid being thereby gradually preheated while it circulates from the preheating tank through the liquid channel and into the evaporator unit for being vaporized therein.

Claims (19)

1. A vapor generator. comprising:
- an evaporator unit comprising an inner chamber for containing a first fluid in a liquid state, and further comprising a preheated liquid inlet, and a vapor outlet, said evaporator unit having a heating device therein which can be activated for vaporizing the first fluid contained in said inner chamber to generate vapor;
- a preheating tank defining an inner chamber and comprising a liquid inlet for injection of the first fluid in a liquid state in said inner chamber, and a liquid outlet; and - an opened liquid channel connecting said preheating tank liquid outlet to said evaporator unit liquid inlet, and establishing free and continuous fluid communication between said preheating tank inner chamber and said evaporator unit inner chamber;
wherein the first fluid in a liquid state injected through said preheating tank liquid inlet is continuously distributed between said evaporator unit inner chamber and said preheating tank inner chamber through said liquid channel, and wherein said heating device of said evaporator unit can be activated for generating a temperature gradient across the liquid-state first fluid contained in said evaporator unit inner chamber, said liquid channel and said preheating tank inner chamber, the first fluid being thereby gradually preheated while it circulates from said preheating tank through said liquid channel and into said evaporator unit for being vaporized therein.

2. The vapor generator according to claim 1, wherein said liquid inlet and said liquid outlet of said preheating tank are significantly spaced apart from each other for allowing the liquid-state first fluid injected in said preheating tank to be preheated in said preheating tank before reaching said preheating tank liquid outlet.

3. The vapor generator according to claim 1, wherein said preheating tank further defines a vapor inlet and a dry vapor exhaust port, said vapor generator further comprising:
- a vapor channel linking said evaporator unit vapor outlet to said preheating tank vapor inlet;
- a passageway extending between said evaporator unit vapor outlet and said preheating tank dry vapor exhaust port, said passageway defining a first portion extending within said vapor channel and a second portion wider than said first portion extending within said preheating tank;
wherein vapor generated from said first fluid in said evaporator unit and flowing out of said evaporator unit vapor outlet and along said passageway towards said dry vapor exhaust port will lose velocity when the vapor passes from said first passageway portion to said relatively wider second passageway portion to the extent of causing liquid-state first fluid droplets carried by the vapor to precipitate in said preheating tank for creating dry vapor to be exhausted through said dry vapor exhaust port.

4. The vapor generator according to claim 3, wherein said preheating tank inner chamber defines a first cross-sectional area, and said vapor channel defines a second cross-sectional area smaller than said first cross-sectional area.

5. The vapor generator according to claim 1, wherein said heating device comprises at least one thermally conductive tube extending in said evaporator unit inner chamber and for allowing a substantially hot heating fluid to flow therein for transferring heat to the first fluid in said inner chamber.

6. The vapor generator according to claim 1, wherein a vapor chamber is defined in said evaporator unit inner chamber above the level of the liquid-state first fluid filling it, said evaporator unit comprising heat-emitting vapor drying means in said vapor chamber. wherein wet vapor occupying said vapor chamber after it is generated in said evaporator unit is dried therein by said heat-emitting vapor drying means.

7. The vapor generator according to claim 6, wherein said evaporator unit comprises evaporation rate control means for controlling the generation rate of vapor in said evaporator unit, thereby controlling the generation rate of dry vapor in said dry vapor generator.

8. The vapor generator according to claim 7, wherein said heating device includes at least one thermally conductive tube extending in said evaporator unit inner chamber and for allowing a substantially hot heating fluid to flow therein for transferring heat to the liquid-state first fluid in said inner chamber, an upper portion of said at least one thermally conductive tube extending in said vapor chamber above the level of the liquid-state first fluid contained in said evaporator unit, said upper portion of said tube forming said vapor drying means.

9. The vapor generator according to claim 8, wherein said at least one heat-transmitting tube defines upstream and downstream ends, and is connected at said upstream and downstream ends to a heating fluid circuit in which the heating fluid is destined to circulate.

10. The vapor generator according to claim 9.
wherein said evaporation rate control means comprise a control valve installed on said heating circuit upstream said at least one heat-transmitting tube.

11. The vapor generator according to claim 9, wherein said evaporator unit includes a flooded heat exchanger, and wherein said evaporation rate control means comprise a control valve installed on said heating circuit downstream said at least one heat-transmitting tube.

12. The vapor generator according to claim 1, wherein said liquid inlet of said preheating tank is connected to a first fluid inlet line, which is provided with at least one preheating device for preheating the first fluid in a liquid state before it is injected in said preheating tank.

13. The vapor generator according to claim 12, wherein said preheating device includes a liquid-state first fluid drainage port for allowing said evaporator unit and said preheating tank to be drained of liquid-state first fluid, said drainage port being linked to a liquid-state first fluid drainage line extending through a first heat exchanger through which said first fluid inlet line also extends for allowing drained first fluid to preheat the first fluid being fed to said preheating tank.

14. The vapor generator according to claim 13, wherein said preheating device further comprises a second heat exchanger through which said first fluid inlet line extends for further preheating the liquid-state first fluid being fed into said preheating tank.

15. The vapor generator according to claim 14, further comprising a heating circuit through which a heating fluid circulates.
said heating circuit being fluidly connected to at least one heat-transmitting tube extending through said evaporator unit inner chamber for allowing the heating fluid to flow therethrough for heating the liquid-state first fluid contained in said evaporator unit inner chamber, and wherein said second heat exchanger is connected to said heating circuit downstream of said heat-transmitting tube for allowing the heating fluid exiting said heat-transmitting tube of said evaporator unit to also preheat the first fluid being fed to said preheating tank.

16. A vapor generator for generating vapor by heating a second fluid with a first fluid, comprising:
- a first fluid circuit comprising an upstream end, a downstream end and an intermediate portion therebetween, for allowing the first fluid to flow from said first fluid circuit upstream end to said first fluid circuit downstream end;
- a second fluid circuit comprising an upstream end, a downstream end and an intermediate portion therebetween for allowing the second fluid to flow from said second fluid circuit upstream end to said second fluid circuit downstream end:

- a heat exchanger unit wherein said intermediate portions of said first and second fluid circuits extend and are in adjacent, thermally-conductive contact for allowing heat transfer from the first fluid to the second fluid whereby liquid state second fluid can be evaporated into gazeous state, said heat exchanger unit comprising on said second fluid circuit a liquid-state second fluid inlet for allowing liquid-state second fluid to flow through said second fluid circuit intermdiate portion. and a gazeous-state second fluid outlet downstream of said liquid-state second fluid inlet for allowing gazeous-state second fluid to exit said heat exchanger unit;
- a control valve on said first fluid circuit for controlling the flow rate of the first fluid in said first fluid circuit;
- a preheating tank part of said second fluid circuit and upstream of said heat exchanger unit, said preheating tank comprising an inner chamber! having a liquid-state second fluid inlet for injecting liquid-state second fluid in said preheating tank inner chamber, and a liquid-state second fluid outlet downstream of said liquid-state second fluid inlet for allowing liquid-state second fluid to exit said preheating tank inner chamber; and - an opened liquid channel linking said preheating tank liquid-state second fluid outlet and said heat exchanger unit liquid-state second fluid inlet, and establishing free and continuous fluid communication between said heat exchanger unit and said preheating tank for allowing the liquid-state second fluid to be freely distributed between said preheating tank inner chamber and said heat exchanger unit;
wherein liquid-state second fluid injected through said preheating tank liquid-state second fluid inlet is gradually preheated as it flows through said preheating tank, said liquid channel and said heat exchanger unit second fluid circuit intermediate portion before being evaporated in said heat exchanger unit by means of the heat transfer from said first fluid circuit intermediate portion.

17. A vapor generator as defined in claim 16, wherein said preheating tank further comprises a gazeous-state second fluid outlet and a gazeous-state second fluid inlet connected to said heat exchanger gazeous-state second fluid outlet with a vapor channel, said preheating tank inner chamber defining a vapor chamber portion between said gazeous-state second fluid inlet and said gazeous-state second fluid outlet, with said preheating tank vapor chamber portion being wider than said vapor channel for allowing gazeous-state second fluid flowing from said vapor channel into said preheating tank vapor chamber to lose velocity for allowing liquid-state second fluid droplets carried by the gazeous-state second fluid to precipitate in said preheating tank for creating dry vapor that will be exhausted through said preheating tank gazeous-state second fluid outlet.

18. A vapor generator as defined in claim 17, wherein said heat exchanger unit is a flooded heat exchanger with said second fluid circuit intermediate portion comprising a heat exchanger inner chamber and said first fluid circuit intermediate portion comprising a number of heat-conducting tubes extending through said heat exchanger inner chamber for allowing said first fluid to flow through said tubes and the second fluid to be contained in said inner chamber, with said tubes being capable of being flooded with liquid-state first fluid in a determined proportion, said control valve being located downstream of said heat exchanger unit on said first fluid circuit whereby the proportion of said heat exchanger which is flooded within said second fluid circuit intermediate portion can be selectively calibrated.

19. A vapor generator as defined in claim 18, further comprising a liquid level controller for controlling the level of liquid-state second fluid in said preheating tank and in said heat exchanger unit inner chamber to maintain the level of liquid-state second fluid within top and bottom determined threshold values, whereby said preheating tank vapor chamber portion is defined above a variable liquid-state second fluid value which will not exceed said top threshold value, and whereby said heat exchanger unit inner chamber also defines a vapor chamber portion above a variable liquid-state second fluid value which will not exceed said top threshold value, with said tubes extending in said heat exchanger unit inner chamber at least partly above said top threshold value for allowing liquid-state second fluid carried by gazeous-state second fluid as it is evaporated in said heat exchanger unit inner chamber to be heated and evaporated through heat transfer from said tubes for creating dry vapor.