SE536398C2 - Turbine with overflow and decreasing cross-sectional area - Google Patents

Abstract

A multi stage turbine for the generation of current comprising a first paddlewheel rotating in a first direction and mounted on a first axle that is connected to a gear system on a first side of the gear system, whereas the multi stage turbine comprises a second paddlewheel rotating in a second direction, counter directional to the first direction and connected to a second axle that is connected to the gear system on the first side of the gear system, whereby the first axle is concentric with and surrounding the second axle, characterized in that the multi stage turbine comprises a third paddlewheel arranged on a third axle and coupled to a second side, opposite the first side, of the gear system, whereby the third paddlewheel is arranged to rotate in the first direction or the second direction, whereby the third paddlewheel have a diameter that is larger than the first and the second paddlewheel and the multi stage turbine comprises a casing that is surrounding the paddlewheels and is forming a passage for the control of the fluid flow with a flow direction from the first paddlewheel against the second paddlewheel, whereby the casing is arranged at a predetermined distance from the first and second paddlewheel for overflow of a part of the fluid flow past the first and second paddlewheel to the third paddlewheel.

Description

DISCLOSURE OF THE INVENTION The invention comprises a multi-stage turbine for generating current comprising a first impeller rotating in a first direction and mounted on a first shaft coupled to a gear system on a first side of the gear system. The multi-stage turbine comprises a second impeller rotating in a second direction, opposite to the first direction, and coupled to a second shaft which is connected to the gear system on the first side of the first gear. The first axis is concentric with and enclosing the second axis.

The multi-stage turbine comprises a third impeller arranged on a third shaft and coupled to a second side, opposite the first side, of The first shaft and the third shaft may be interconnected and form a common shaft. The first and the third shaft can also be a unit which forms a shaft passing through the gear system. The third impeller is arranged to rotate in the first direction or the second direction. The third impeller has a diameter that exceeds the diameter of the first and second impellers. the gear system.

According to an example of the invention, the multi-stage turbine comprises a fourth impeller coupled to a fourth shaft which is coupled to the gear system on the other side of the gear system. In the example, the fourth shaft is concentric with and enclosing the third shaft and the fourth impeller is arranged to rotate in an opposite direction relative to the third impeller. In the event that the fourth impeller is present, this can also be enclosed by the cover.

By adding a fourth impeller, additional energy in the fluid flow can be utilized. the gear system is constructed according to known technology for connecting three input shafts and an output shaft and four input shafts and one output shaft, respectively. In the example of the invention where the multi-stage turbine comprises a first, a second and a third impeller, these are coupled to a first, a second 535 398 and a third shaft which enters the gear system. The second shaft is arranged concentrically and encloses the first shaft on one side of the gear system and the third shaft is arranged on the opposite side of the gear system. The centers of all input shafts are arranged in the same plane. The first shaft and the third shaft may be interconnected to form a common shaft.

The first and the third shaft can also be a unit which forms a shaft passing through the gear system. The first and the second shaft, with associated first and second impellers, are arranged to rotate on different hobs.

How a gear system according to the above, with three input shafts and an output shaft, is arranged is already known. In the example of the invention where the multi-stage turbine comprises a first, a second, a third and a fourth impeller, these are coupled to a first, a second, a third and a fourth shaft which enter the gear system. The second axis is arranged concentrically and enclosing the first axis and the fourth axis is arranged concentrically and enclosing the third axis. The first and second axles are arranged on one side of the gear system and the third and fourth axles are arranged on the opposite side of the gear system.

The centers of all input shafts are arranged in the same plane. The first and second axles, with associated first and second impellers, are arranged to rotate in different directions. The third and fourth axles, with associated third and fourth impellers, are arranged to rotate in opposite directions.

How a gear system as above, with four input shafts and one output shaft, is arranged is already known.

The force in the output shaft is used to use a generator to generate current according to a method known from before.

According to an example of the invention, the multi-stage turbine comprises a housing which encloses the first, second and third impellers and forms a passage for controlling a fluid flow with flow direction from the first impeller to the second impeller. The housing is arranged at a predetermined distance from the first and second impellers for overflowing a part of the fluid flow past the first and second impellers to the third impeller. By arranging the three impellers in this way, it is possible to make better use of the energy in the fluid flow.

The present invention combines prior art in a new way. In order to minimize losses and obtain better part load properties, the invention intends to replace turbines equipped with guide vanes with turbines equipped with impeller pairs so that optimal energy can be extracted regardless of the size of the fluid flow. According to, multi-stage turbines are arranged comprising at least two stages with 3 or 4 impellers in modules. In the case of a multi-stage turbine according to the invention comprising 3 impellers, the first two impellers are arranged in a first pair of impellers and the third impeller is arranged separately. In the case where a multi-stage turbine according to the invention comprises 4 impellers, the first two impellers are arranged in a first pair and the two remaining impellers are arranged in a second pair. To minimize losses, the two impellers included in a pair of impellers rotate in the opposite direction. The more pairs of impellers that are combined, the more energy can be extracted from the fluid flow. Furthermore, modules comprising multi-stage turbines with 3 or 4 impellers can be arranged in serial and / or parallel arrangements. the invention For a multi-stage turbine according to the invention, the energy conversion becomes smaller for each stage. A subset of the fluid flow is therefore allowed to pass the first stage impeller in its outer part so that at least the third impeller in the second stage has a significantly higher supply of energy and thereby the possibility of a greater energy conversion. As the rotating impeller is more efficient in its outer part, partly because the speeds there are greater but also because the torque arm is larger, the smaller diameter in the first step will make better use of the fluid flow close to the inner diameter. In addition, in order to allow subsequent impellers to have a greater fluid flow in their outer part, the outer diameter of the impeller is increased for each step downstream. According to an example of the invention, the multi-stage turbine comprises an inner housing, enclosing the first, second and third shafts and the gear system. The inner casing advantageously has an outer diameter which increases in the downstream direction. In the case where the multi-stage turbine also contains a fourth impeller with a fourth shaft, the fourth shaft is also enclosed by the inner casing. This will increase the flow rate downstream.

According to a further advantageous example of the invention, the third, and the fourth impeller in this case, has a diameter which exceeds the diameter of the first and second impellers by about 20 - 40 ° / °. According to an example of the invention, the housing has a direction downstream decreasing inner diameter. In another example of the invention, the housing has an inner diameter increasing in the downstream direction. Both of these different arrangements will affect the flow picture. In a further advantageous example of the invention, the distance between the housing and the third and fourth impellers is about 80-90% smaller in relation to the distance between the housing and the first and second impellers.

In an example of the invention, the multi-stage turbine comprises a funnel for controlling the flow of fluid towards the passage and the impellers. The funnel can be arranged against the housing or in the vicinity of the housing without being directly connected to the housing for that matter. If a funnel is used, this will increase the flow of fluid through the turbine. In yet another example of the invention, the multi-stage turbine comprises a control device for controlling the fluid flow inside the housing. The use of control devices enables the fluid flow to be controlled, which can enable more efficient use of the impellers. 536 398 In an advantageous example of the invention, the multi-stage turbine comprises a housing which encloses the impellers and forms a passage for controlling the flow of fluid with flow direction from the first impeller to the second impeller, the casing being arranged at a predetermined distance from the first about 45-45% of the first. and the second paddle wheel for overflowing a portion of the fluid flow past the first and second paddle wheels to the third and in cases where it is the fourth paddle wheel.

In another example of the invention, at least two multi-stage turbines are arranged parallel to each other. In a further example of the invention, at least two multi-stage turbines are arranged in series with each other. In another example of the invention, where at least two multi-stage turbines are arranged in series, the downstream multi-stage turbine has a housing with an inner diameter larger than the housing of an upstream multi-stage turbine. In yet another example of the invention, where at least two multi-stage turbines are arranged serially in a system, a downstream series-mounted multi-stage turbine impeller has a larger outer diameter than an upstream series-mounted multi-stage turbine to be able to assimilate the fluid flow in the overflow. This makes it possible to make better use of the energy in the fluid flow.

In an example of the invention where at least two multi-stage turbines are arranged serially in a system, a flow separator can be arranged at the upstream multi-stage turbine for the purpose of controlling a part of the fluid flow to the passage and the turbine and / or a part of the fluid flow in overflow past the casing of the upstream arranged multi-stage turbine.

In another example of the invention where at least two multi-stage turbines are arranged in series, an upstream arranged multi-stage turbine comprises an outer casing enclosing the casing and forming an outer passage between the casing and the outer casing for controlling the overflowing fluid flow to the downstream flow turbine.

In an example of the invention, at least one multi-stage turbine is connected via the gear system to a generator for power production.

The examples presented above can be combined to optimize the effect of the invention, but can also be used separately to achieve increased effect.

BRIEF DESCRIPTION OF THE FIGURES The present invention will now be described in detail with reference to the figures, in which: Figure 1 shows a first example of a multi-stage turbine according to the invention Figure 2 shows a second example of a multi-stage turbine according to the invention Figure 3 shows a third example of a multi-stage turbine according to the invention Figure 4 shows a fourth example of a multi-stage turbine according to the invention Figure 5 shows a first example of how two modules are arranged in a series embodiment Figure 6 shows a second example of how two modules are arranged in a series embodiment Figure 7 shows an example of how two modules are arranged in a parallel embodiment DESCRIPTION OF THE EMBODIMENT EXAMPLE 1 Figure 1 shows a multi-stage turbine 101 comprising a first paddle wheel 102, a second paddle wheel 105 and a third paddle wheel 107. Figure 1 shows the invention according to which the first and second paddle wheels 102, 105 have a smaller diameter than the third paddle wheel 107. The fluid flow is allowed there by passing the first and second impellers 102, 105 via a passage 110. The first impeller 102 communicates directly with the third impeller 107 via a first shaft 103 and a third shaft 108, these rotate in the same direction. The first shaft 103 and the third 108 shaft may be interconnected and form a common shaft. The first and third shafts 103, 108 may also be a unit forming a shaft passing through the gear system 104.

The second impeller 105 is connected to the gear system 104 via a second shaft 106 which is concentrically mounted relative to the first shaft 103 and which rotates in the opposite direction. the gear system 104 drives via a shaft arrangement the generator 120 which thereby produces electrical energy.

The passage 110 refers to at least the difference between the outer diameter of the third paddle wheel 107 and the outer diameter of the first and / or the second paddle wheel 102, 105. If the first paddle wheel 102 has a different outer diameter than the second paddle wheel 105, the passage 110 refers to at least the difference between the outer diameter of the third impeller 107 and the larger outer diameter of the first or second impeller 102, 105.

The first paddle wheel 102 and / or the second paddle wheel 105 and / or the third paddle wheel 107 may be surrounded by a housing 109. In the example of Figure 1, the first, second and third paddle wheels 102, 105, 107 are surrounded by the housing 109. The passage 110 refers to then the distance between the housing 109 and the first or second impeller 102, 105.

Figure 2 shows a multi-stage turbine 101 comprising a first impeller 102, a second impeller 105 and a third impeller 107, enclosed by a housing 109 comprising a funnel 115. The housing encloses the first, second and the third impeller 102, 105, 107, the first, second and third shafts 103, 106, 108 and the gear system 104. The funnel 115 is arranged upstream of the housing 109, and has a larger diameter upstream than downstream of the housing 109, which allows the funnel 115 to control a fluid flow into against the multi-stage turbine's 101 impellers.

Figure 3 shows a multi-stage turbine 201 comprising a first impeller 202, a second impeller 205, a third impeller 207 and a fourth impeller 211.

Figure 3 shows the invention according to which the first and second shoe covers 202, 205 have a smaller outer diameter than the third and fourth shoe covers 207, 211. The fluid flow is thereby allowed to pass the first and the second shoe covers 202, 205 via a passage 210. The first the shoe housing 202 communicates with the third shoe housing 207 via a first shaft 203 and a third shaft 208. The first, second, third and fourth shoe wheels 202, 205, 207, 2011, respectively, rotate in the same direction as the first, second, third, and fourth, respectively. the shaft 203, 206, 208, 212 and the impeller, respectively, are connected. The first shaft 203 and the third 208 shaft may be interconnected and form a common shaft. The first and third shafts 203, 208 may also be a unit forming a shaft passing through the gear system 204. In case the first and third shafts 203, 208 are one unit, the first and third shafts 203, 208 will rotate in the same direction. If the first and third shafts 203, 208 are interconnected, they can rotate in the same direction or in different directions. If the first and third shafts rotate in different directions, this is achieved according to a coupling method known from before.

The second and fourth shoe wheels 205, 211 may rotate in the same direction or in different directions depending on how the first and third shoe wheels rotate. The first shoe cover 202 will always rotate in the opposite direction to which the second shoe cover 205 rotates, and the third shoe cover 207 will always rotate in the opposite direction as the fourth shoe cover 211 rotates. The second shaft 206 is concentrically mounted relative to the first shaft 203. The fourth shaft 212 is concentrically mounted relative to the third shaft 208. The first and second shoe wheels 202, 205 are connected 535 398 to the gear system 204 via the first shaft and the second shaft 203, 206, and the third and fourth impellers 207, 211 are connected to the gear system 204 via the third and fourth shafts 208, 212. The gear system drives the generator 120 via a shaft arrangement which thereby produces electrical energy.

Figure 3 further shows a multi-stage turbine consisting of four impellers, 202, 205, 207, 211, where the first two 202, 205 have a smaller diameter than the second two 207, 211 and thus allow fluid flow to pass in the passage 210 directly to the third and then the fourth impeller 207, 211.

The passage 210 refers at least to the difference between the outer diameter of the third and / or fourth impeller 207, 211 and the outer diameter of the first and / or the second impeller 202, 205. If the first and second impellers 202, 205 have different outer diameters the passage 210 refers at least to the difference between the outer diameter of that of these impellers having the largest outer diameter and that of the third and fourth impellers 207, 211 having the largest outer diameter, if the third and fourth impellers 207, 211 have different outer diameter. The first paddle wheel 202 and / or the second paddle wheel 205 and / or the third paddle wheel 207 and / or the fourth paddle wheel 211 may be surrounded by a housing 209. In the example of Figure 3, the first, second, third and fourth paddle wheels 202, 205 are surrounded. , 207, 211 of the housing 209. The passage 210 then refers to the distance between the housing and the first and second paddle wheels 202, 205.

Figure 4 shows a multi-stage turbine 201 comprising a first impeller 202, a second impeller 205, a third impeller 207 and a fourth impeller 211, enclosed by a housing 209 comprising a funnel 215. The housing encloses the first, second, third and the fourth impeller 202, 205, 207, 211, the first, second, third and fourth axles 203, 206, 208, 212 and the gear system 204. The funnel 215 is arranged upstream of the housing 209, and has a larger diameter upstream than downstream of the housing 209, allowing the hopper 215 to direct a flow of fluid toward the multi-stage turbine 201 with a first paddle wheel 202, a second paddle wheel 205, a third paddle wheel 207 and a fourth paddle wheel 211.

Figure 5 shows two modules 321, 322, a first module 321 with a multi-stage turbine 201 comprising four impellers 202, 205, 207, 211 and a second module 322 with a multi-stage turbine 101 comprising three impellers 102, 105, 107. The first module arranged upstream 321 is provided with overflow in the passage 210. Between the outside of the housing 209 on the first module arranged upstream 321 and the inside of the housing 109 on the second module arranged downstream 322 an outer passage 319 is formed. The fluid flow to the second module 322 comes partly via the first module 321 but also via an outer passage 319. The second module 322 which lies downstream is also provided with overflow in its two first impellers 102, 105 so that some part of the fluid flow to the second module 322 can reach the third module 322's third impeller 107 directly via the passage 110. The second module lying downstream 322 is formed with a larger diameter of its respective impellers 102, 105, 107 than the f first module 321 impeller 202, 205, 207, 211.

The output shafts of both modules are connected via a shaft arrangement to a generator 120 which converts mechanical energy into electrical energy.

Furthermore, both the first upstream module 321 and the second downstream module 322 include an inner housing 214; 114. For the first upstream module, the inner housing 214 encloses the first, second, third and fourth shafts 203, 206, 208, 212 and the gear system 204. For the second downstream module, the inner housing 114 encloses the first, second and third the shaft (not pictured) and the gear system (not pictured).

The inner housings 214, 114 have a downstream increasing outer diameter which together with the housings 209; 109 provides a downstream decreasing flow area around the two inner housings 214; 114, which provides an increased flow rate. An alternative embodiment to this is that the second module is provided with four impellers similar to the first module and / or that the first module is provided with three impellers. The two modules can also have the same number of impellers.

Figure 6 shows an arrangement where two modules 321, 322 are arranged in series, and where the housing 209 of the first upstream module 321 is surrounded by an outer housing 318, an outer passage 319 being formed between the housing 209 of the upstream first module 321 and the outer casing 318. In Fig. 6, the outer casing 318 is arranged against the casing 109 of the downstream second module 322, but the outer casing 318 may also be arranged in another way.

Figure 7 shows two modules 323 arranged in a parallel arrangement. Here too, the modules can alternatively be provided with three or four impellers in embodiments according to Figures 1 and 2. The output shafts of both modules 323 are connected via a shaft arrangement with a generator 120 which converts mechanical energy into electrical energy.

The examples of the invention described above are not to be construed as limiting but only as examples of embodiments of the invention. Furthermore, the various embodiments of the invention can be freely combined.

Claims (10)

535 358 l3> REQUIREMENTS 1. A multi-stage turbine (101; 201) for generating power comprising a first impeller (102; 202) rotating in a first direction and mounted on a first shaft (103; 203) coupled to a gear system (104; 204) on a first side of the gear system (104; 204), the multi-stage turbine (101; 201) comprising a second impeller (105; 205) rotating in a second direction, opposite the first direction, and coupled to a second shaft (106; 206) which is connected to the gear system (104; 204) on the first side of the gear system (104; 204), the second shaft (106; 206) being concentric with and enclosing the first shaft (103; 203), characterized in that the multi-stage turbine (101 ) comprises a third impeller (107) arranged on a third shaft (108) and coupled to a second side, opposite the first side, of the gear system (104), the third impeller (107) being arranged to rotate in the first direction or the second direction, the third impeller (107) having a diameter exceeding the diameter of the first and second impellers (102, 105), and the multi-stage turbine (101) includes a housing (109) enclosing the impellers (102, 105, 107) and forming a passage (110) for controlling a fluid flow flow direction from the first impeller (102) to the second impeller (105), the housing (109) being disposed at a predetermined distance from the first and second impellers (102, 105) to overflow a portion of the fluid flow past the first and second impellers. second paddle wheel (102, 105) to subsequent paddle wheel (107). A multi-stage turbine (201) according to claim 1, comprising a fourth impeller (211) coupled to a fourth shaft (212) coupled to the gear system (204) on the other side of the gear system (204), the fourth shaft (212) ) is concentric with and enclosing the third shaft (208), the fourth impeller (211) being arranged to rotate in an opposite direction relative to the third impeller (207). 535 398 lll 4.. A multi-stage turbine (101) according to claim 1, wherein an inner housing (114) enclosing the first, second and third shafts (103, 106, 108) and the gear system (104) has an increasing diameter in the downstream direction. A multi-stage turbine (201) according to claim 2, wherein an inner housing (214) enclosing the first, second, third and fourth shafts (203, 206, 208, 212) and the gear system (204) has one, in the downstream direction, increasing outer diameter. 5.. A multi-stage turbine (101) according to claim 1 or 3, wherein the third impeller (107) has an outer diameter exceeding the outer diameter of the first and second impellers (102, 105) by 20-40%, 6.. A multi-stage turbine (201) according to any one of claims 2 or 4, wherein the third and fourth impellers (207, 211) have an outer diameter exceeding the outer diameter of the first and second impellers (202, 205) by 20-40%, 7.. A multi-stage turbine (101) according to any one of claims 1, 3 or 5, wherein the distance between the housing (109) and the third impeller (107) is 80-90 ° / ° smaller relative to the distance between the housing (109) and the first and the second impeller (102, 105). 8.. A multi-stage turbine (201) according to any one of claims 2, 4 or 6, wherein the distance between the housing (209) and the third and fourth impellers (207, 211) is 80-90% smaller in relation to the distance between the housing (209) and the first and second paddle wheels (202, 205). 9.. A multi-stage turbine (101; 109) according to any one of the preceding claims, wherein the multi-stage turbine (101; 109) comprises a funnel (115; 215) for controlling the flow of fluid towards the passage (110; 210) and the impellers (102; 202, 105; 205). , 107; 207, 21 1). A multi-stage turbine (101; 201; 321; 322) according to any one of the preceding claims, wherein the multi-stage turbine (101; 201; 321; 322) is connected via the exchange system (104; 204) to a generator (120) for power production.