Power generating apparatus using flowing water

Abstract

A power generating apparatus using flowing water for rotating a shaft. Blades are mounted at a certain distance apart from each other on two straight sections of a chain. When the blades are immersed in water, water passes through the blades in the first straight section and then passes through the blades in the second straight section. The blades are caught on a stopper provided on the chain to be maintained in an oblique line. Direction adjusting devices are on curved sections. The oblique directions of the blades are in mutual opposition. The energy from the flow speed of water is changed into circulating power of the chain by the blades. The sprockets are driven by the chain (111), and drive rotating shafts.

Claims

1. A power generating apparatus using flowing water, wherein: a plurality of blades 120 are mounted at a certain distance apart from each other on a chain of a chain circulating device 110; a first straight section S1 and a second straight section S2 in which the chain 111 moves in a straight line are formed on the chain circulating device 110; when the blades 120 mounted on the chain circulating device 110 are immersed in water, water passes through the blades 120a in the first straight section S1 and then passes through the blades 120b in the second straight section S2, and the blades 120a are caught on a stopper 130 provided on the chain 111 such that the blades 120b in the first straight section S1 and the blades in the second straight section S2 are maintained in an oblique line with respect to the chain 111; first and second direction adjusting device 140 and 150 are arranged in a first and second curved section C1 and C2 in which the chain 111 of the chain circulating device 110 passes sprockets 115 and 116; the oblique directions of the blades 120a in the first straight section S1 and the blades 120b in the second straight section S2 are arranged in mutual opposition by the first and second direction adjusting devices 140 and 150; the energy from the flow speed of water is changed into the circulating power of the chain 111 by the blades 120a in the first straight section S1 and the blades 120b in the second straight section S2; and the sprockets 115 and 116 are driven by the chain 111, and the sprockets 115 and 116 drive rotating shafts 117 and 118 such that a rotational power is generated at the rotating shafts 117 and 118, wherein the upper and lower ends of the blade 120 are pivotably mounted on an attachment 112 of the chain 111 by a pin 113, and one side surface of the blade is caught on the stopper 130 that extends obliquely downward from one end of the attachment 112, and thus is maintained to be oblique with respect to the chain 111 or flow direction of water and is changed into an arrangement state by a lever 121 mounted on the upper end.

2. The power generating apparatus of claim 1, wherein: the chain circulating device 110 is installed in a frame 160 having a hexahedral structure; the rotating shafts 117 and 118 face each other; the sprockets 115 and 116 are mounted at the upper end of the rotating shafts 117 and 118; the chain 111 circulates around the sprockets 115 and 116; and the sprockets are also mounted at the lower end of the rotating shafts 117 and 118.

3. The power generating apparatus of claim 1, wherein the lever 121 comprises a lower vertical part 122 fitted into and fixed on the upper end of the blade 120, a horizontal part 120 bent and extending from the upper end of the lower vertical part 122, and an upper vertical part 124 upwardly bent and extending from the end of the horizontal part 123.

4. The power generating apparatus of claim 1, wherein the first direction adjusting device 140 is mounted in the frame to be disposed in a first curved section C1 of the chain circulating device 110, and comprises a guide recess part 141 to guide the rotation of the lever 121 while the blade 120 is passing the first curved section C1.

5. The power generating apparatus of claim 4, wherein the second direction adjusting device 150 is mounted in the frame 160 to be disposed in a second curved section S2 of the chain circulating device 110, and comprises a guide concave part 151 to guide the rotation of the lever 121 while the blade 120 is passing the second curved section C2.

Description

BRIEF DESCRIPTION OF DRAWINGS

(1) FIG. 1 is a perspective view illustrating a power generating apparatus using flowing water according to a first embodiment of the present invention.

(2) FIG. 2 is a plan view illustrating a power generating apparatus using flowing water according to a first embodiment of the present invention.

(3) FIG. 3 is a schematic view illustrating an outer product vector of water acting on a blade disposed in a first straight section section.

(4) FIG. 4 is a perspective view illustrating a chain mounted with a blade.

(5) FIG. 5 is a plan view illustrating a first direction adjusting device.

(6) FIG. 6 is a plan view illustrating a second direction adjusting device.

(7) FIG. 7 is a perspective view illustrating a power generating apparatus using flowing water according to a second embodiment of the present invention.

(8) FIG. 8 is a plan view illustrating a power generating apparatus using flowing water according to a second embodiment of the present invention.

(9) FIG. 9 is a magnified view illustrating a chain mounted with a blade of FIG. 8.

BEST MODES FOR CARRYING OUT THE INVENTION

(10) Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings.

(11) Referring to FIGS. 1 and 2, a power generating apparatus using flowing water according to a first embodiment of the present invention is shown. Here, a plurality of blades 120 are mounted at a certain distance apart from each other on a chain of a chain circulating device 110. A first straight section S1 and a second straight section S2 in which the chain 111 moves in a straight line are formed on the chain circulating device 110. When the blades 120 mounted on the chain circulating device 110 are immersed in water, water passes through the blades 120a in the first straight section S1 and then passes through the blades 120b in the second straight section S2, and the blades 120 are caught on a stopper 130 provided on the chain 111 such that the blades 120a in the first straight section S1 and the blades 120b in the second straight section S2 are maintained in an oblique line with respect to the chain 111. First and second direction adjusting device 140 and 150 are arranged in a first and second curved section C1 and C2 in which the chain 111 of the chain circulating device 110 passes sprockets 115 and 116. The oblique directions of the blades 120a in the first straight section S1 and the blades 120b in the second straight section S2 are arranged in mutual opposition by the first and second direction adjusting devices 140 and 150. The energy from the flow speed of water is changed into the circulating power of the chain 111 by the blades 120a in the first straight section S1 and the blades 120b in the second straight section S2. The sprockets 115 and 116 are driven by the chain 111, and the sprockets 115 and 116 drive rotating shafts 117 and 118 such that a rotational power is generated at the rotating shafts 117 and 118.

(12) Referring to FIGS. 2 and 3, the power generating apparatus using flowing water according to the first embodiment of the present invention acts as follows.

(13) As shown in FIG. 2, when water flows from the front side to the rear side, i.e., in a direction of an arrow 191, water hits the blades disposed in an oblique direction. As shown in FIG. 3, a horizontal component Fa acts on the blade 120 such that the blade 120 moves in the direction of the horizontal component Fa. Thus, the chain 111 is moved from the left side to the right side in the first straight section S1 by the blade 120. In this case, n blades may be disposed in the first straight section S1. Thus, since n horizontal components are added, a high output can be acquired.

(14) Also, the flow energy of water acts on the blade 120 in the second straight section S2, allowing the chain 111 of the second straight section S2 to be moved from the right side to the left side by the blade 120.

(15) Accordingly, the circulation kinetic energy of the chain become equal to the sum of the horizontal components acting on the blades in the first straight section and the horizontal components acting on the blades in the second straight section. Thus, the conversion efficiency of the flow energy into the rotational energy may be very high, and the rotating power of the rotating shaft may drive a generator to produce electrical energy.

(16) Referring again to FIG. 1, the chain circulating device 110 is installed in a frame 160 having a hexahedral structure. Two rotating shafts 117 and 118 face each other. The sprockets 115 and 116 are mounted at the upper end of the rotating shafts 117 and 118. The chain 111 circulates around the sprockets 115 and 116. Also, sprockets are mounted at the lower end of the rotating shafts 117 and 118, and a chain circulates around the sprockets.

(17) Thus, the circulation movement of the chain 111 drives the sprockets 115 and 116, and the sprockets 115 and 116 rotate the two rotating shafts 117 and 118 to acquire a rotational power from one or both of the two rotating shafts 117 and 118.

(18) Referring to FIGS. 3 and 4, the upper and lower ends of the blade 120 are pivotably mounted on an attachment 112 of the chain 111 by a pin 113. One side surface of the blade 120 is caught on the stopper 130 that is downwardly bent from one end of the attachment 112, and thus is maintained to be oblique with respect to the chain 111 (or flow direction of water) and is changed into an arrangement state by a lever 121 mounted on the upper end.

(19) Referring to FIG. 4, the lever 121 includes a lower vertical part 122 fitted into and fixed on the upper end of the blade 120, a horizontal part 123 bent and extending from the upper end of the lower vertical part 122, and an upper vertical part 124 upwardly bent and extending from the end of the horizontal part 123.

(20) Also, the lower vertical part 122 of the lever 121 is fixed on the upper end so as to be biased to one side portion based on the center of the blade 120 through the attachment 112, and the rotation of the lower vertical part 122 is not interfered by the attachment 112.

(21) The slope of the blade 120 that is obliquely disposed is determined by the width W of the stopper 130. Accordingly, the width W of the stopper 130 is determined in consideration of the flow speed and flow rate of water.

(22) As shown in FIG. 4, the attachment 112 may be fixed on a link plate 111a of the chain 111 by a rivet (not shown), or may be formed integrally with the link plate 111a of the chain 111 when manufactured.

(23) Referring to FIG. 5, the first direction adjusting device 140 is mounted in the frame 160 to be disposed in a first curved section C1 of the chain circulating device 110, and includes a guide recess part 141 to guide the rotation of the lever 121 while the blade 120 is passing the first curved section C1.

(24) Thus, when the blade 120 passing through the first straight section S1 reaches a start point A of the first curved section C1, the lever 121 is adhered closely to the guide recess part 141. Thereafter, while the blade 120 is passing through the first curved section C1 by the chain 111, the lever 121 moves along the guide recess part 141, allowing the blade 120 to be disposed in the inversely oblique direction opposite to the oblique direction of the first straight section S1 when moving to the second straight section S2 through the first curved section C1.

(25) Referring to FIG. 6, the second direction adjusting device 150 is mounted in the frame 160 to be disposed in a second curved section C2 of the chain circulating device 110, and includes a guide concave part 151 to guide the rotation of the lever 121 while the blade 120 is passing the second curved section C2.

(26) Thus, when the blade 120 passing through the second straight section S2 reaches a start point C of the second curved section C2, the lever 121 is adhered closely to the guide concave part 151. Thereafter, while the blade 120 is passing through the second curved section C2 by the chain 111, the lever 121 moves along the guide concave part 151, allowing the blade 120 to be disposed in the inversely oblique direction opposite to the oblique direction of the second straight section S2 when moving to the first straight section S1 through the second curved section C2.

(27) The power generating apparatus using flowing water according to the first embodiment of the present invention operates as follows.

(28) When water passes the blade 120a of the first straight section S1, the flow energy of water allows the blade 120 to be pushed from the left side to the right side. In this case, the chain 111 is moved from the left side to the right side by the blade 120 in the first straight section S1, and the blades 120 of the second straight section S2 are also moved from the right side to the left side by water, allowing the chain 111 of the second straight section S2 to move from the right side to the left side. Thus, the chain 111 performs an orbital circulation movement, and thus the sprockets 115 and 116 coupled to the chain 111 rotate, generating rotational energy at the rotating shafts 117 and 118 by the rotation of the sprockets 115 and 116.

(29) In this case, the blade 120a of the first straight section S1 is disposed in an oblique direction, but is disposed in an inversely oblique direction by the first direction adjusting device 140 when reaching the second straight section S2 through the first curved section C1. Also, the blade 120b of the second straight section S2 is again disposed in the oblique direction while passing the second direction adjusting device 150. Thus, the blades 120 are disposed in the oblique and inversely oblique directions in the first and second straight sections S1 and S2, respectively.

(30) Referring to FIGS. 7 and 9, a power generating apparatus using flowing water according to a second embodiment of the present invention is shown. Here, a chain circulating device 210 is mounted in a frame 260, and a blade 220 includes an upper one side portion and a lower one side portion thereof rotatably mounted onto an attachment 212 of a chain 211 by a pin 213, allowing a plurality of blades 220 to be mounted at a certain distance apart from each other on a chain 211 of a chain circulating device 210. A first straight section D1 and a second straight section D2 in which the chain 211 moves in a straight line are formed on the chain circulating device 210. When the blades 220 mounted on the chain circulating device 210 are immersed in water, water passes through the blades 220 in the first straight section D1 and then passes through the blades 220 in the second straight section D2. Horizontal guiding rods 230 and 240 are mounted in the frame 260, and when the blades 220 pass the first straight section D1, the sides of the blades 120 are caught on the horizontal guiding rod 230 such that the blades 220 become oblique. When the blades 220 pass the second straight section D2, the sides of the blades 120 are caught on the horizontal guiding rod 240 such that the blades 220 become inversely oblique. Thus, energy from the flow speed of water is changed into migration energy of the chain 211 by the blades 220 in the first straight section D1 and the blades 220 in the second straight section D2. Sprockets 215 and 216 are driven by the chain 211, and the sprockets 215 and 216 drive rotating shafts 217 and 218 such that a rotational power is generated at the rotating shafts 217 and 218.

(31) In the power generating apparatus using flowing water according to the second embodiment of the present invention, when water flows from the front side to the rear side, i.e., in a direction of an arrow 291 of FIG. 8, water hits the blades disposed in an oblique direction. As shown in FIG. 3, a horizontal component Fa acts on the blade 220 such that the blade 220 moves in the direction of the horizontal component Fa. Thus, the chain 211 is moved from the left side to the right side in the first straight section D1 by the blade 220. In this case, n blades may be disposed in the first straight section S1. Thus, since n horizontal components are added, a high output can be acquired.

(32) Also, the flow energy of water acts on the blade 220 in the second straight section D2 as described above, allowing the chain 211 of the second straight section D2 to be moved from the right side to the left side by the blade 220.

(33) Accordingly, the circulation power of the chain become equal to the sum of the horizontal components acting on the blades 220 in the first straight section D1 and the horizontal components acting on the blades 220 in the second straight section D2. Thus, the conversion efficiency of the flow energy into the rotational energy may be very high, and the rotating power of the rotating shaft may drive a generator to produce electrical energy.

(34) The chain circulating device 210 is installed in a frame 260 having a hexahedral structure. Two rotating shafts 217 and 218 face each other. The sprockets 215 and 216 are mounted at the upper end of the rotating shafts 217 and 218, respectively. The two chains 211 circulate around the sprocket 215 disposed at the upper end of the rotating shafts 217 and 218 and the sprocket 216 disposed at the lower end of the rotating shafts 217 and 218, respectively.

(35) Thus, the circulation movement of the chain 211 drives the sprockets 215 and 216, and the sprockets 215 and 216 rotate the two rotating shafts 217 and 218 to acquire a rotational power from one or both of the two rotating shafts 217 and 218.

(36) The blade 220 has an oblique inclination angle varying according to a gap between the horizontal guiding rods 230 and 240 and the chain 211.

(37) The power generating apparatus using flowing water according to the second embodiment of the present invention operates as follows.

(38) When water passes the blade 220 of the first straight section D1, the flow energy of water allows the blade 220 to be pushed from the left side to the right side. In this case, the chain 211 is moved from the left side to the right side by the blade 220 in the first straight section D1, and the blades 220 of the second straight section D2 are also moved from the right side to the left side by water, allowing the chain 211 of the second straight section D2 to move from the right side to the left side. Thus, the chain 211 performs an orbital circulation movement, and thus the sprockets 215 and 216 coupled to the chain 211 rotate, generating rotational energy at the rotating shafts 217 and 218 by the rotation of the sprockets 215 and 216.

(39) In this case, the blade 220 is obliquely disposed in the first straight section D1 by the horizontal guiding rod 230. However, when the chain 211 passes the sprocket 215, the blade 220 can freely pivot because there is no factor that restricts the blade 220. Accordingly, the blade 220 becomes upright in the flow direction of water. Thereafter, the blade 220 is inverse-obliquely disposed in the second straight section D2 by the horizontal guiding rod 240, and when the chain 211 passes the sprocket 216, the blade 220 can freely pivot because there is no factor that restricts the blade 220. Accordingly, the blade 220 becomes upright in the flow direction of water.

(40) The power generating apparatus using flowing water according to the first and second embodiments of the present invention has an advantage of highly efficiently converting energy from flowing water into rotational power by minimizing a useless movement section existing in a typical water turbine.