KR101267535B1 - High-efficiency electric power generation system for electric power generation - Google Patents

Abstract

PURPOSE: A high efficiency electricity generation system using hydraulic pressure is provided to actuate a hydraulic motor connected to an electricity generator after converting the potential energy of a rolling member into hydraulic energy, thereby increasing the generating efficiency. CONSTITUTION: A high efficiency electricity generation system using hydraulic pressure includes a rolling member(51), a rotary frame(19a), a pressing plate(19b), multiple hydraulic cylinders(17), multiple pneumatic cylinders(15), and a hydraulic motor(23). The rolling members are installed at both ends of a pulling bar(27), and the rotary frame is hinged at a supporting plate part(13a). The pressing plate at the upper side of the rotary frame supports the rolling members. The multiple hydraulic cylinders installed at the lower side of the rotary frame support the rotary frame. The multiple pneumatic cylinders placed at the sides of the hydraulic cylinders upwardly restore the pressing plate which has been downwardly pressed after the rolling member passed through the pressing plate. The hydraulic motor is actuated by the hydraulic pressure from the hydraulic cylinders, and generates a rotational torque. [Reference numerals] (41b) Controller; (AA) System

Description

High-efficiency power generation system using hydraulics {HIGH-EFFICIENCY ELECTRIC POWER GENERATION SYSTEM FOR ELECTRIC POWER GENERATION}

The present invention relates to a high efficiency power generation system using hydraulic pressure.

In response to global warming and depletion of fossil energy, theoretical and experimental studies on renewable energy such as solar, wind, hydro, tidal and tidal currents are being actively conducted. In addition, interest in power generation as an alternative energy source in relation to such renewable energy is increasing.

By the way, the above-mentioned various renewable energy production facilities such as solar power plants, impulse generators, dams, etc. are very large in size and limited in the installation place, and thus they cannot be produced on a small scale around living.

For example, if there is a small renewable power generation facility in each neighborhood or apartment complex, it would be possible to reduce the economic burden by using home-grown electricity without having to purchase electricity. In reality, however, there are no suitable facilities around our lives to produce renewable energy.

The present invention has been made to solve the above problems, it is possible to produce electricity by using a load applied when rolling the rolling member rolling the rolling member with a load around the rotation axis, and in particular, the potential energy of the rolling member After switching to the, driving the hydraulic motor connected to the generator is to provide a high-efficiency power generation system using the hydraulic power generation efficiency is high and the timing of the power generation can be adjusted.

High efficiency power generation system using the hydraulic pressure of the present invention for achieving the above object, the frame having a horizontal support plate; A rotating shaft installed vertically in the central portion of the support plate and rotating axially by an external force; A horizontal pull bar fixed to an upper portion of the rotating shaft and rotating by rotating the shaft of the rotating shaft; A rolling member mounted to both ends of the tow bar and driven by the rotation of the tow bar to roll; A plurality of pivot frames hinged to the support plate and arranged symmetrically about the rotation axis and capable of vertically pivoting; A plurality of pressing plates provided on an upper portion of each of the rotation frames to support the rolling members and disposed on the moving paths of the rolling members; A plurality of hydraulic cylinders installed at a lower portion of the rotating frame to support the rotating frame, the pressing plate being compressed when the pressing plate is rotated downward by the load of the rolling member and discharging hydraulic pressure to the outside; A plurality of pneumatic cylinders located on the side of the hydraulic cylinder and returning the pressing plate which was pressed downward after the rolling member passes through the pressing plate; A hydraulic motor which operates by receiving hydraulic pressure discharged from the hydraulic cylinder to generate a rotational torque; It characterized in that it comprises a generator for producing electric power by receiving the rotational force of the hydraulic motor.

In addition, a driven gear is fixed to the rotary shaft, and the support plate, a drive gear for rotating the rotary shaft through the driven gear by rotating the motor and the reducer connected to the motor, and the reducer coupled to the driven gear. Characterized in that provided.

In addition, the pneumatic cylinder is to support the rotating frame on the side of the hydraulic cylinder, the pressing plate is compressed by the lowering, the power generation system, the air discharged from the pneumatic cylinder when the pneumatic cylinder is compressed Compressed air tank for receiving and temporarily storing, and a compressor for supplementing the compressed air to the compressed air tank is characterized in that it further comprises.

In addition, the accumulator for storing the pressure discharged from the hydraulic cylinder is installed between the hydraulic cylinder and the hydraulic motor.

In addition, the upper portion of each pressing plate is characterized in that the inclined surface portion inclined upward in the moving direction of the rolling member.

In addition, the tow bar is for mounting a rolling member on the tow bar, a holder fixed to both ends of the tow bar, and one end is connected to the holder pin can be rotated up and down, the extended end of the rotating shaft of the cloud member It is characterized in that the traction link is connected to.

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The high-efficiency power generation system and power generation method using the hydraulic pressure of the present invention made as described above, by rotating the rolling member having a load around the rotation axis and can produce electricity by using the load applied when the rolling member rolls, in particular, rolling member After changing the potential energy of the hydraulic energy, and driving the hydraulic motor connected to the generator, the power generation efficiency is high and the timing of power generation can be adjusted.

1 is a partial plan view of a high efficiency power generation system using hydraulic pressure according to an embodiment of the present invention.
FIG. 2 is a plan view of the power generation system shown in FIG.
3 is a view for explaining the movement of the pressing plate by the rolling member in the power generation system shown in FIG.
4 is a view showing the overall configuration of a high-efficiency power generation system using hydraulic pressure according to an embodiment of the present invention.

Hereinafter, one embodiment according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a partial plan view of a high efficiency power generation system using hydraulic pressure according to an embodiment of the present invention, and FIG. 2 is a plan view of the power generation system shown in FIG. 3 is a view for explaining the movement of the pressing plate by the rolling member in the power generation system shown in FIG.

As shown, the high-efficiency power generation system using hydraulic pressure, according to the present embodiment, takes the form of an octagon and is arranged horizontally on the ground and has a support plate portion 13a in the center, and the support. Eight pivot frames 19a hinged to the plate portion 13a and rotatable up and down, pressing plates 19b fixed to an upper surface of each of the pivot frames 19a, and a plurality of hydraulic plates supporting the pressing plates 19b. Vertically perpendicular to the cylinder 17 and the pneumatic cylinder 15, the hydraulic motor (41c in FIG. 4) and the generator 43 for producing electricity using the hydraulic pressure generated in the hydraulic cylinder 17, and the support plate 13a Rotating shaft 31 which is supported by the shaft and the rotatable shaft, coupled to the upper end of the rotating shaft 31, the pull bar 27 extending to both sides and the rolling member mounted on both ends of the pull bar 27 ( 51).

First, the main frame 13 is a structure having an octagonal planar structure, and as shown in FIG. 4, the main frame 13 has the support plate portion 13a above the center thereof. The outer portion of the support plate 13a is provided with a plurality of hinge coupling portion (37). The hinge coupling portion 37 is a portion for supporting the pivot frame 19a so as to be rotatable up and down on the support plate portion 13a, and is symmetrically disposed about the rotation shaft 31.

The rotating frame 19a is a member that can be rotated up and down while being supported by the hinge coupler 37 and is symmetrical about the rotation shaft 31. In addition, each of the rotatable frames 19a can be moved independently without interfering with each other.

The pressing plate 19b installed on the upper portion of the rotation frame 19a is disposed on the rotation path of the rolling member 51 and provides a path through which the rolling member 51 can roll. The rolling member 51 travels above the pressing plate 19b according to the shaft rotation of the rotation shaft 31.

In particular, the inclined surface portion 19c is provided on the upper surface of the pressing plate 19a. The inclined surface portion 19c is an inclined plate that is inclined upward in the traveling direction of the arrow c direction of the rolling member 51, and prevents the jaw from occurring when the rolling member 51 runs and crosses the pressing plate 19a.

As will be described later, when the rolling member 51 is raised to each pressing plate 19a, the pressing plate 19a sags downward by the weight of the rolling member 51, and the rolling member 51 is the pressing plate 19b. Since the driving continues along the path provided, each pressing plate 19b repeatedly descends and climbs in accordance with the running of the rolling member 51. That is, when the rolling member 51 passes and descends, then it rises.

In any case, the inclined surface portion 19c eliminates the step between the lowered pressing plate 19b and the lowering pressing plate 19b to enable smooth running of the rolling member 51. That is, the rolling member 51 serves to raise the height of the rolling member 51 so that the rolling member 51 smoothly rises on the pressing plate 19b in advance of the lowering.

In addition, one hydraulic cylinder 17 and two pneumatic cylinders 15 are provided below the respective rotation frames 19a.

The hydraulic cylinder 17, the upper end of the pin is connected to the bottom of the rotating frame 19a and the lower end is pin connected to the main frame (13). The hydraulic cylinder 17 is compressed when the rotating frame 19a is lowered and serves to transmit hydraulic energy to the outside.

The hydraulic energy generated in each of the hydraulic cylinders 17 is transferred to the accumulator (41a in FIG. 4), and then used to drive the hydraulic motor 41c.

The pneumatic cylinder 15 is located on both sides of the hydraulic cylinder 17, the upper end is pinned to the rotation frame (19a) and the lower end is pinned to the main frame (13). The pneumatic cylinder 15 serves to support the rotating frame 19a by the force of air. That is, when the rotating frame 19a sags downward, it is compressed, and the rolling member 51 passes through the rotating frame 19a and expands to return the rotating frame 19a to its original position.

In order to stably perform the operation of the pneumatic cylinder 15, an initial position restoring unit 39 is added. As shown in FIG. 4, the initial position restoring unit 39 includes a compressed air tank 39c for temporarily storing compressed air discharged from the pneumatic cylinder 15, and compressed air in the compressed air tank 39c. Compressor (39a) for further supply of the pressure reduction valve (39b) for reducing the pressure of the compressor (39a).

The compressed air tank 39c temporarily stores the air of the pneumatic cylinder 15 when the pressing plate 19b is pressed downward, and stores the compressed air when the load applied to the pressing plate 19b is removed. Send back to cylinder 15.

In addition, when the air pressure in the compressed air tank 39c is insufficient, the compressor 39a operates to increase the pressure. When the pressure in the compressed air tank 39c is higher than the preset pressure, the pressure reducing valve 39b is operated to stop the operation of the compressor 39a.

The initial position restoring unit 39 assists the pneumatic cylinder 15 to return the rotation frame 19a to its initial position.

On the other hand, the rotating shaft 31 is a rotating shaft vertically supported by the support plate portion 13a, and rotates the turning weight portion 21. The pivot weight portion 21 includes a pull bar 27 fixed to an upper end of the rotation shaft 31 and a rolling member 51 linked to both ends of the pull bar 27 and driven by the rotation of the draw bar 27. .

The pull bar 27 is a rod-shaped member extending to both sides with the rotation shaft 31 at the center to rotate by the rotation of the rotation shaft 31.

In addition, a holder 27a is fixed to both ends of the pull bar 27, and a pull link 29 is connected to the pin 27b to the holder 27a. The shaft 51a is fitted to the extended end of the traction link 29. The shaft 51a is a rotation axis of the rolling member 51. As a result, the rolling member 51 is movable up and down in the direction of the arrow d in the state linked to the draw bar (27).

A driven gear 33 is fixed to the rotation shaft 31. The driven gear 33 is a spur gear that is fixed to the rotating shaft 31 and rotates together with the rotating shaft 31.

In addition, a motor 23, a speed reducer 25, and a drive gear 35 are provided on the side of the rotation shaft 31. The motor 23 serves to generate a rotational torque and drives the reducer 25. In addition, the reduction gear 25 rotates the drive gear 35 by reducing the rotational force of the motor 23 at a constant speed.

The drive gear 35 transmits the rotational force of the reduction gear 25 to the driven gear 33 in engagement with the driven gear 33 to rotate the rotation shaft 31. As the rotary shaft 31 rotates, the pivot weight portion 21 rotates, and the rolling member 51 sequentially displaces the rotation frame 19a.

4 is a view showing the overall configuration of a high efficiency power generation system 11 using hydraulic pressure according to an embodiment of the present invention.

Referring to the drawings, it can be seen that each of the hydraulic cylinder 17 is connected to the hydraulic unit 41. The hydraulic unit 41 is for operating the generator using the hydraulic energy generated in the hydraulic cylinder 17, and accumulator 41a for receiving the hydraulic oil extruded from the hydraulic cylinder 17 via the check valve 41m. ), A controller 41b for adjusting the pressure of the accumulator 41a to a desired pressure and sending the hydraulic pressure to the hydraulic motor 41c, and receiving and rotating the hydraulic pressure passing through the controller 41b to drive the generator 43. Hydraulic motor 41c is included.

In addition, the hydraulic oil passing through the hydraulic motor 41c is temporarily stored in the hydraulic oil storage tank 41f through the cooler 41d and the filter 41e, and then the hydraulic cylinder 17 is operated by the operation of the pneumatic cylinder 15. As it expands, it returns to the hydraulic cylinder 17 via the suction filter 41g and the check valve 41n.

On the inlet side of the hydraulic cylinder 17, a discharge side check valve 41m and a suction side check valve 41n are provided. The discharge side check valve 41m is opened when the hydraulic cylinder 17 is compressed to allow hydraulic oil to flow to the accumulator 41a side. At this time, the suction side check valve 41n is blocked by the pressure difference.

The suction side check valve 41n is opened when the pressing plate 19b is raised. It goes without saying that the discharge side check valve 41m is closed while the suction side check valve 41n is opened.

In some cases, air may be sucked into the hydraulic circuit, and at this time, the hydraulic operation efficiency is very low. In this embodiment, in order to eliminate such a problem, an air bleed valve 41p and a check valve 41q are provided on the discharge port side of the hydraulic cylinder 17. The air bleed valve 41p removes air generated in the hydraulic circuit, and the check valve 41q prevents air outside the circuit from being sucked into the circuit.

While the hydraulic oil flows through the hydraulic motor 41c and into the hydraulic oil storage tank 41f, the hydraulic oil is partially converted into thermal energy by the pipeline resistance and the driving loss of the hydraulic motor 41c. Is processed by the cooler 41d installed on the downstream side of the hydraulic motor 41c.

In addition, the filter 41e serves to maintain the cleanliness of the hydraulic oil by removing foreign substances generated in the hydraulic circuit circulating the hydraulic oil.

The power generation method using the high efficiency power generation system using the hydraulic pressure of the present embodiment having the above configuration is made as follows.

First, when the motor 23 is driven, the tow bar 27 rotates, and the tow bar 27 pulls the rolling member 51 connected to the tow link 29 and the shaft 51a. Rotate. The rolling member 51 rotates on the pressing plate 19b while rotating.

The rolling member 51 presses the pressing plate 19b downward with the potential energy at the upper portion of the pressing plate 19b. As the pressing plate 19b is displaced downward, the hydraulic cylinder 17 connected to the pressing plate 19b converts the potential energy of the rolling member 101 into hydraulic energy. The hydraulic energy converted by the hydraulic cylinder 17 is transferred to the hydraulic motor 41c, and the generator 43 is operated by the hydraulic motor 41c to produce electricity. Hydraulic energy generated by the hydraulic cylinder 17 is accumulated in the accumulator 12 and used when necessary.

On the other hand, the hydraulic cylinder 17 is compressed when receiving the load of the rolling member 51 and the operation of the hydraulic unit 41 to accumulate energy and to send the hydraulic oil back to the hydraulic cylinder 17 using the accumulated energy and The pneumatic cylinder 15 returns to the initial position.

In the hydraulic unit 41, the hydraulic oil storage tank 41f is installed at a higher altitude than the hydraulic cylinder 17. By doing so, the potential energy due to the weight of the hydraulic oil can be increased to increase the suction efficiency of the hydraulic cylinder 17. In order to allow the hydraulic oil to be sucked into the hydraulic cylinder 17, since it takes time to be sucked only by the vacuum pressure, it is possible to shorten the suction time and maximize the suction efficiency by increasing the potential energy by the weight of the hydraulic oil.

Basically, the power generation method of the power generation system according to the present embodiment is to generate electricity by using a load applied when the rolling member 51 on the pressing plate 19b runs, and in particular, the load of the rolling member 51 is increased. It is converted to hydraulic pressure and converted into electrical energy.

The method of converting the potential energy of the rolling member 51 into hydraulic energy can be variously changed.

The reason why the accumulator 41a is applied in the hydraulic unit 41 is that hydraulic energy can be accumulated in the accumulator 41a, and the hydraulic motor 41c can be operated when necessary. Since energy other than hydraulic energy is very difficult to store, the accumulator 41a and the hydraulic cylinder 17 are applied.

Anyway, since the hydraulic energy can be stored and used when necessary, the hydraulic energy can be accumulated in the accumulator 12 at a low power consumption time, and then generate power at a high power usage time.

The hydraulic cylinder 17 serves as a pump, for example, by extruding and sucking hydraulic oil through compression and expansion. Normally, the hydraulic cylinder is driven by the hydraulic pressure discharged from the pump, but in the case of the present embodiment, the hydraulic cylinder 17 acts as a pump. In order for the hydraulic cylinder 17 having such a structure to act as a pump, suction efficiency is a problem, but by installing the hydraulic oil storage tank 41f at a higher altitude than the hydraulic cylinder 17, the potential energy due to its own weight is increased to increase the suction efficiency. Increase it.

In general, induction generators have a specified number of revolutions. For example, a four-pole induction generator can generate power only by maintaining 1800 to 1850 rpm, which is otherwise difficult to maintain. In the case of wind power generators, a gearbox is installed on the blade shaft of the rotating chain to drive the generator. In the case of low or large wind speeds, the rotation speed is not easy to control, and thus the efficiency is about 22%.

In addition, the number of revolutions of the generator also directly affects the quality of the output electricity. In other words, if the frequency change of electricity is severe, it can not be connected to the system, the number of revolutions of the generator is a significant problem. Accordingly, in the present invention, when the hydraulic oil discharged by installing the hydraulic motor 41c in a variable manner is reduced, the swash plate of the hydraulic motor 41c is reduced to control the rotation speed of the hydraulic motor 41c, and when the discharge flow rate is large, the swash plate angle The rotation speed of the generator 14 is kept constant by controlling the rotation speed of the hydraulic motor 41c by increasing.

On the other hand, as described above, the initial position restoration unit 39 is applied in order to reduce the consumption of energy of the power generation system 11 as much as possible to induce the return of the hydraulic cylinder 17.

That is, the pneumatic cylinder (15) is to help the expansion of the hydraulic cylinder (17) while being compressed and expanded. As similar to the pneumatic cylinder, for example, a spring method can be considered, but the stability and efficiency of operation does not reach the pneumatic cylinder (15).

The reason for applying the initial position restoring unit 39 is to rapidly return the pressing plate 19b to the initial position. Since the pressure plate 19b has to be quickly returned to the top dead center which is the first position after the pressing plate 19b is pressed, a maximum return is very important.

When the spring method is applied, the elastic modulus of the spring must be large for rapid return of the pressing plate 19b. However, when the elastic modulus of the spring is large, the pressing plate 19b is not pressed well, and thus the amount of output power is greatly reduced. In addition, the spring elasticity is reduced due to frequent operation, the spring replacement cycle is shortened.

As described above, the high-efficiency power generation system and the power generation method using the hydraulic pressure according to the embodiment of the present invention are just described, for example, and various changes and modifications can be made without departing from the technical spirit of the present invention.

11: Power generation system 13: Main frame 13a: Support plate part
15: pneumatic cylinder 17: hydraulic cylinder 19a: rotating frame
19b: pressure plate 21: turning weight 23: motor
25: reducer 27: tow bar 27a: holder
27b: Pin 29: Towing link 31: Rotating shaft
33: driven gear 35: drive gear 37: hinge coupling portion
39: Initial position restoration unit 39a: Compressor 39b: Pressure reducing valve
39c: compressed air tank 41: hydraulic unit 41a: accumulator
41b: Controller 41c: Hydraulic motor 41d: Cooler
41e: Filter 41f: Hydraulic oil storage tank 41g: Suction filter
41m, 41n: Check valve 41p: Air bleed valve 41q: Check valve
43: generator 51: cloud member 51a: shaft

Claims (10)

A structure having an octagonal planar structure, comprising: a main frame 13 having a octagonal shape at the center and having a support plate portion 13a horizontally disposed on the ground;
A rotating shaft 31 vertically installed at a central portion of the support plate portion 13a and axially rotated by an external force;
A horizontal pull bar 27 fixed to an upper portion of the rotary shaft 31 and rotating by the shaft rotation of the rotary shaft 31;
A rolling member (51) mounted to both ends of the tow bar (27) and driven in rolling motion by following the rotation of the tow bar (27);
Eight pivot frames (19a) hinged to the support plate portion (13a), symmetrically disposed about the rotation axis (31), and independently rotatable without interfering with each other;
It is disposed symmetrically about the rotating shaft 31 is installed on the outer portion of the support plate portion (13a), and supports the pivot frame (19a) up and down rotatable to the support plate portion (13a) to the hinge coupling portion (37) A plurality of hinge coupling parts 37 to be rotatable up and down while being supported);
It is provided on the upper portion of each of the rotating frame (19a) to support the rolling member 51, is disposed on the movement path of the rolling member 51 so that the rolling member 51 to the axial rotation of the rotary shaft (31) The upper surface is provided, and the upper surface is provided with an inclined surface portion 19c which is inclined upward in the traveling direction of the rolling member 51, so that the pressing plate 19b which prevents the jaw from occurring when the rolling member 51 runs and falls. )and;
It is installed in the lower portion of the rotating frame (19a) to support the rotating frame (19a), when the pressing plate (19b) is pressed by the load of the rolling member 51 is rotated downward and discharge the hydraulic pressure to the outside A plurality of hydraulic cylinders 17;
Located in the side of the hydraulic cylinder 17, and the plurality of pneumatic cylinder (15) for returning the pressing plate (19b) that was pressed downward after the rolling member 51 passes through the pressing plate (19b) and ;
A hydraulic motor 41c which operates by receiving hydraulic pressure discharged from the hydraulic cylinder 17 to generate a rotational torque;
A generator 43 for producing electric power by receiving the rotational force of the hydraulic motor 41c;
A compressed air tank (39c) for receiving and temporarily storing air discharged from the pneumatic cylinder (15) when the pneumatic cylinder (15) is compressed;
A compressor (39a) replenishing the compressed air to the compressed air tank (39c);
The pneumatic cylinder (15) supports the pivot frame (19a) at the side of the hydraulic cylinder (17), and the pressing plate (19b) is compressed by being lowered,
The tow bar 27 is for mounting the rolling member 51,
A holder 27a fixed to both ends,
One end is connected to the holder 27a by a pin 27b and is rotatable up and down, and an extension end thereof is provided with a traction link 29 connected to the shaft 51a of the rolling member 51. High efficiency power generation system using hydraulic pressure.
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