KR102312150B1 - Power generating device using working fluid - Google Patents

Abstract

Disclosed is a power generating device using pressure of gas or liquid. In the power generating device using a working fluid according to the present invention, a plurality of cylinders driven by working fluid, any one selected from gas or liquid are disposed such that forward and backward directions of piston rods are different and when pressure of a working fluid which is gas or fluid is inputted simultaneously into each cylinder to allow each piston in the cylinder to reciprocate, a rack fixed to the ends of the two piston rods reciprocates while engaging with one rack gear to rotate the two piston rods in different directions. The rotational movement in different directions is converted into the rotational movement in the same direction by means of a one-way clutch to enable a driving shaft (30) for providing power to a load to be driven. According to the present invention, loss of energy and loss of goods can be reduced.

Description

Power generating device using working fluid

The present invention relates to a power generating device capable of generating power by the pressure of gas or liquid, and more particularly, a plurality of cylinders are arranged to have different forward and backward directions of a piston rod, and a working fluid made of gas or fluid pressure is simultaneously input to each cylinder and each piston of the cylinder reciprocates, the rack fixed to the two piston rod terminals reciprocates while engaged with one rack gear, rotates in different directions, and rotates in different directions It relates to a power generating device using a working fluid that generates power that is converted into rotational motion in the same direction by a one-way clutch to rotate a drive shaft.

In general, a steam engine is an engine that obtains power by supplying high-pressure steam from a boiler to a cylinder and reciprocating a piston using the expansion and condensation of steam. It refers to the prime mover that moves the piston.

Steam engines and internal combustion engines are composed of a crankshaft, crank arm, and crank pin, and a crank mechanism that converts reciprocating motion into rotational motion by attaching another link to the shaft shifted from the center of rotation and constraining one end to make a linear motion. (crank mechanism) rotates the drive shaft, is mounted on the transmission (Transmission) side of the crankshaft is configured to include a flywheel that maintains the rotational force of the crankshaft by inertial force to reduce imbalance.

In such a steam engine and internal combustion engine, the configuration of the device is complicated by the crank mechanism, and the increase in the device is increased by the flywheel, so that energy loss occurs when the moving direction of the piston is reversed in the crank mechanism. Since this energy loss corresponds to 30% of the explosive force generated by combustion in an internal combustion engine, there is a problem in that linear motion cannot be efficiently converted into rotational motion.

In addition, when the exhaust discharged from the cylinder is released into the atmosphere, there is a problem in that the exhaust loss is large, noise and vibration are generated by the pulsation of the drive shaft, and the weight of the device is increased by the flywheel and the inferiority ratio is reduced.

Moreover, fuel used in internal combustion engines is the main culprit of environmental pollution due to the limitation of the depletion of petroleum energy, the natural resource, and the explosion heat of the engine raising the temperature of the atmosphere.

A power generating device for solving the above problems is disclosed in US Patent No. 7765803.

This device is provided with a cylindrical valve having four working fluid passages in intersecting directions at regular intervals, and each working fluid of the valve is connected to four cylinder heads arranged side by side, and the four Two cylinders form a pair, and the lower end is connected by a communication part to enable movement of the working fluid between the cylinders. , the rack gear has a drive shaft capable of converting bidirectional rotation into unidirectional rotation to transmit power to a load, and a power transmission mechanism capable of continuously rotating the valve in one direction by interlocking with the drive shaft. will become

This device is composed of four cylinders, the rear ends of the two cylinders are connected by a connecting pipe, so that the movement of the working fluid is possible. Two racks reciprocate alternately, and the rack gears meshing with each of these four racks rotate in different directions. In addition, rotational motion in different directions is converted into rotational motion in the same direction by a one-way clutch and transmitted to the drive shaft. In contrast, the efficiency of the engine can be increased by reducing the inertial energy loss when converting the linear motion of the piston into the rotational motion of the drive shaft.

This device allows the valve to supply the working fluid directly from the cylinder head, so the space of the device can be reduced. However, there is a problem in that the arrangement design of the valve and the cylinder is not free.

In addition, since the rear ends of the two cylinders are connected to each other so that the working fluid moves between the two cylinders, when two discharge ports and a return port are provided in one valve, as a result, four cylinders are required and the weight of the device is reduced. increases, and the working fluid is alternately input to both cylinders, and one end of both cylinders is connected to a communication part, and as the working fluid moves between the pistons, as the working fluid is compressed between the pistons, a pressure loss is generated, resulting in power There is a problem that the generation efficiency is lowered.

JP 3886992 B2 (2018. 12. 01.) US 7765803 B2 (2010. 08. 03.)

An object of the present invention is to provide a power generating device capable of generating power with the pressure of gas or liquid.

In order to solve the structural problem in which energy loss occurred in the conventional double cylinder engine, the use of petroleum energy is excluded and rotational power can be generated without a crank mechanism by using a power source selected from gas and liquid, and An object of the present invention is to provide a power generating device in which energy loss can be reduced when linear motion is converted into rotational motion of a drive shaft.

Another object of the present invention is to avoid a method in which the rear ends of two cylinders are connected to each other so that the working fluid moves between the two cylinders, and the working fluid is directly supplied to both cylinders in different operating directions at the same time, so that one valve An object of the present invention is to provide a power generating device capable of improving engine efficiency while reducing the weight of the device by enabling power generation with only two cylinders when two discharge ports and a recovery port are provided.

Another object of the present invention is to provide a power generating device capable of freely designing the arrangement between the valve and the cylinder by connecting the valve and the cylinder to the supply line to supply and recover the working fluid.

Another object of the present invention is that the chambers of both cylinders are connected to move between the cylinders of the working fluid, so that the working fluid is compressed between the piston rods to solve the problem that the engine efficiency may be lowered, and high output power can be produced. It is to provide a power generating device using the working fluid to be present.

Another object of the present invention is to install a recovery pump between the discharge port of the cylinder and the booster pump, recover the entire amount of the working fluid and reuse it, to provide a power generating device using a working fluid that can increase the efficiency of the working fluid It intended.

The purpose of the present invention and its technical problems are not limited to the technical problems described above. Accordingly, other technical problems not mentioned will be clearly understood by those of ordinary skill in the art to which the present invention belongs from the following description.

A technical feature for achieving the intended object of the present invention is a power generating device capable of generating power by the pressure of a gas or liquid, comprising: at least one pair of reciprocating means operating in alternating directions and simultaneously operating; Transmission means installed to correspond to the reciprocating means, converting the reciprocating motion of the reciprocating means into rotational motion, and a conversion means for reversing the rotational direction of the transmission means rotating in opposite directions by the reciprocating means with alternating traveling directions a rotation means for converting the linear motion generated by the reciprocating motion means into rotational motion in the same direction; a drive shaft rotating by the rotating means and supplying power to a load; a working fluid supply means for supplying a working fluid selected from gas or liquid to drive the pair of reciprocating means; A power transmission mechanism for continuously operating the working fluid supply means in conjunction with the drive shaft is provided to generate power by the pressure of the working fluid.

According to a technical feature of the present invention, in the reciprocating means, at least a pair of a first cylinder and a second cylinder are arranged with different forward and backward traveling directions of the first piston rod and the second piston rod, and the first cylinder and the second cylinder The first piston rod and the second piston rod of the second cylinder may further include a supply means for supplying a working fluid to operate in different forward and backward travel directions.

According to a technical feature of the present invention, the rotating means includes first and second racks fixed to the first piston rod of the first cylinder and the second piston rod of the second cylinder; It is characterized in that it includes a first rack gear and a second rack gear that is engaged with the first and second racks, fixed to the drive shaft to rotate the drive shaft.

According to a technical feature of the present invention, the working fluid supply means includes a booster pump; a supply tank for storing the pressure of the working fluid generated by the booster pump; a recovery tank in which the working fluid discharged from the supply tank to generate power and circulated to the booster pump is stored; and a valve means for supplying the working fluid discharged from the supply tank to the plurality of first and second cylinders, and supplying the working fluid discharged from the first cylinder and the second cylinder to the recovery tank.

According to a technical feature of the present invention, the power transmission mechanism includes a first pulley fixed to the drive shaft and rotating; a second pulley fixed to the fixed shaft of the valve and rotating; It is characterized in that it is possible to drive by the pressure of gas or liquid, characterized in that it is composed of a timing belt wound between the first pulley and the second pulley and continuously rotates the valve in one direction in conjunction with the drive shaft. .

According to a technical feature of the present invention, the converting means includes becoming a one-way clutch.

According to a technical feature of the present invention, in the valve means, the valve means passes through in a direction crossing the outer circumferential surface of the cylindrical body at a predetermined distance and alternately opens and closes when rotating at least two first and second discharge ports and a first , a second recovery port, wherein the first discharge port and the first recovery port are formed in a direction parallel to each other, and the second discharge port and the second recovery port are perpendicular to the first discharge port and the first recovery port It consists of a cylindrical valve formed in parallel with each other in the in-direction and rotatably fixed to a fixed shaft, and the first and second discharge ports and the first and second recovery ports are connected to the first cylinder and the second cylinder. However, in the first and second discharge ports, the working fluid is simultaneously supplied to the first and second cylinders with different opening and closing times, respectively, in the forward and backward directions of the first piston rod and the second piston rod of the first cylinder and the second cylinder. These are supplied to be alternated with each other, and the working fluid discharged from the first cylinder and the second cylinder can be introduced and circulated while the opening and closing times of the first and second recovery ports are different, respectively.

As described above, the present invention is such that a plurality of cylinders are arranged so that the forward and backward directions of the piston rod are different, and when the pressure of gas or fluid is simultaneously input to each cylinder by the working fluid supply means, each piston of the cylinder reciprocates, The rack fixed to the two piston rod ends rotates in different directions while reciprocating while engaged with one rack gear, and the rotational motion of the drive shaft rotating in different directions is performed by a one-way clutch. It is converted into rotational motion in the same direction to produce power.

Therefore, the present invention is composed of four cylinders in which the rear ends of the two cylinders are connected by a connecting pipe in the conventional double cylinder engine, and when the piston rod reciprocates by alternately supplying a high-pressure fluid to the two cylinders, it interlocks with it Unlike a device in which four racks reciprocate alternately, and the rack gears meshed with each of these four racks rotate in different directions, the linear movement of the piston rods in different forward and backward directions in the two cylinders is simultaneous. will occur

According to the present invention, a working fluid is simultaneously supplied to two cylinders by rotating a valve having two discharge ports and a return port in one direction using the pressure of gas or liquid, and a rack, a rack gear, and a one-way clutch By driving the drive shaft to generate power required for the load, there is almost no driving energy, friction loss, and cooling loss according to the crank weight in engines of conventional conventional steam engines and internal combustion engines, as well as eliminating the need for a cooling system. there is

In addition, it generates power by efficiently using energy by reducing exhaust loss, friction loss, heat loss and cooling loss, and inertial energy loss of valves in general engines that generate power while repeatedly generating heat by repeating compression and explosion. There is an effect that can make it happen.

Excluding exhaust loss, cooling loss, and crankshaft drive loss from the heat engine as described above, it has the effect of improving the existing thermal efficiency from 25 to 35% to 95%, significantly reducing the fuel consumption rate required for power generation compared to the existing engine, It has the effect of reducing the loss of energy and the loss of goods.

In addition, the high-pressure working fluid discharged is recovered by the recovery pump and reused, thereby preventing energy loss and remarkably improving the efficiency of the engine.

In addition, since the pressure of the working fluid is simultaneously input to the two cylinders and discharged at the same time, in the US patent of the similar prior art, both cylinders are connected by a communication part to generate secondary compression between the pistons, so that the power generation efficiency is improved It has the effect of being able to produce high-output power by solving the lowered problems.

1 is a plan view showing the mechanical configuration of an embodiment of the present invention;
2 is a cross-sectional view showing the mechanical configuration of the embodiment of the present invention;
3 is a block diagram showing a working fluid supply line according to an embodiment of the present invention;

The features and advantages of the present invention will be more clearly understood by the embodiments described by the accompanying drawings.

The application of the present invention is not limited by the configuration and arrangement of components described in the embodiments of the present invention or shown in the drawings. The present invention is capable of being embodied in other embodiments and of being carried out in various ways. Also, the expressions and predicates used in the embodiments with respect to terms such as device, orientation of elements, etc. are used only to simplify the description of the present invention, and do not indicate or imply that the related device or element should simply have a specific orientation. does not For example, terms such as "first" and "second" are used in the embodiments and claims describing the present invention, but such terms are not intended to indicate or imply relative importance.

In one embodiment, the present invention has been described with reference to the accompanying drawings, but those skilled in the art can make various changes without departing from the scope of the present invention from these descriptions. Therefore, the present invention is not limited to the presented embodiments, and within the equivalent scope of the technical spirit of the present invention and the technical spirit described in the claims to be described below by those of ordinary skill in the technical field to which the present invention pertains. should be interpreted in

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

Figure 1 is a plan view showing the mechanical configuration of the embodiment of the present invention, Figure 2 is a cross-sectional view showing the mechanical configuration of the embodiment of the present invention, Figure 3 is a block diagram showing the working fluid supply line of the embodiment of the present invention.

1, the power generating device using the working fluid of the present invention includes at least one pair of reciprocating means operating in different directions and simultaneously operating; a working fluid supply means for supplying a working fluid for sequentially driving the pair of reciprocating means; a plurality of rotation means provided with a conversion means for reversing the rotational direction and installed to correspond to the reciprocating means and converting the linear motion generated by the reciprocating means into rotational motion; a drive shaft 30 that rotates by the rotation means; It is configured to include a power transmission mechanism for operating the working fluid supply means in conjunction with the drive shaft (30).

The working fluid may be high-pressure air or hydraulic fluid.

The reciprocating means consists of a first cylinder 10 and a second cylinder 20 fixed in parallel on the base 60 .

The first cylinder 10 is fixed to the first fixing bracket 711 fixedly installed on the base 60 , and the second cylinder 20 is fixed to the second fixing bracket 712 .

The first cylinder 10 is divided into a first chamber and a second chamber 113 forming both spaces by a first piston 110, and a first piston rod ( 111) is exposed to the outside of the first cylinder 10 by the sealing structure.

The second cylinder 20 is divided into a third chamber and a fourth chamber 213 that form both spaces by a second piston 210, and one side of the second piston 210 has a second piston rod ( 211 is exposed to the outside of the second cylinder 20 by the sealing structure.

The first cylinder 10 and the second cylinder 20 form at least a pair and are installed side by side in one direction, and the first piston rod 111 and the second piston rod 211 move forward and backward in opposite directions. The first piston rod 111 and the second piston rod 211 are reciprocated by the pressure of the working fluid supplied to the first cylinder 10 and the second cylinder 20 from the working fluid supply means.

At this time, the supplied working fluid is simultaneously supplied to the first chamber 112 of the first cylinder 10 and the third chamber 212 of the second cylinder 20 to the first piston rod 111 and the second piston rod. (211) is able to move forward and backward in a direction crossing each other.

The rotating means is a pair of first and second racks 230 and 240, and while meshing with the first and second racks 230 and 240, is fixed to the drive shaft 30 and the drive shaft (30) It is configured to include a first rack gear 231 and a second rack gear 241 capable of rotating the.

The first rack 230 is fixed to the tip of the first piston rod 111 while being guided by the first guide rail 232 fixed in parallel with the movement direction of the piston on the base 60 so that it can move forward and backward, The second rack 240 is also fixed to the tip of the second piston rod 211 fixed in parallel with the movement direction of the piston on the base 60 so that it can move forward and backward.

The first rack 230 and the second rack 240 are respectively guided by the first guide rail 232 and the second guide rail 242 while the side surfaces are supported by the support means.

The first rack gear 231 and the second rack gear 241 are provided with rotation direction switching means.

The rotation direction switching means is preferably composed of a one-way clutch (250, 251).

One-way clutch gear is an energy amplifying device, which is a technical device that can obtain large power with a small amount of force.

As is well known, these one-way clutches 250 and 251 are shaft joints having a structure that transmits power in only one direction, allowing rotation in one direction and blocking rotation in the other direction to prevent power transmission. As it performs a role of interception, a detailed description of the configuration will be omitted.

The support means includes a support ring 243 that is installed in a bearing 233 fixed to the base 60 between the first rack 230 and the second rack 240 and rotates horizontally, and the support ring ( The outer peripheral surface of 243 is supported on the side surfaces of the first rack 230 and the second rack 240 to support the first rack 230 and the second rack 240 moving forward and backward.

The first rack gear 231 and the second rack gear 241 are fixed to the drive shaft 30 at a predetermined distance, and the first rack gear 231 meshes with the first rack 230 , and the second rack gear 241 meshes with the second rack 240 .

Accordingly, the first rack 230 and the first rack gear 231 are driven by the first cylinder 10 , and the second rack 240 and the second rack gear 241 are the second cylinder 20 . is driven by and rotates the drive shaft 30 .

At this time. The first rack 230 and the second rack 240 mounted on the piston rod drive the first rack gear 231 and the second rack gear 241 mounted on the drive shaft 30. This device amplifies energy it is a device The diameters of the first rack gear 231 and the second rack gear 241 are determined according to each case, and force transmission is most effective at a 90° angle, which is compared to the crank structure by operating at a 90° angle from the beginning. efficiency is maximized.

Here, in the first rack gear 231 and the second rack gear 241 , the first cylinder 10 and the second cylinder 20 rotate in different directions because the movement directions of the piston rods are staggered. The rotation direction of one rack gear is changed to be the same as the rotation direction of the other rack gear by the clutches 250 and 251 so that the driving shaft 30 can be continuously rotated.

The driving shaft 30 is rotatably fixed to a third fixing bracket 713 and a fourth fixing bracket 714 fixed on the base 60 to rotate the first rack gear 231 and the second rack gear 241 . It rotates and transmits the power required for the load, and it continuously rotates in the same direction by the one-way clutches 250 and 251 and transmits the power to the load side.

The working fluid supply means is composed of a booster pump 40 , a supply tank 41 , a recovery tank 42 and a valve 43 means to continuously supply the working fluid to the first cylinder 10 and the second cylinder 20 . supply

The booster pump 40 generates pressure in the working fluid.

The power transmission mechanism includes a first pulley 51 fixed to the driving shaft 30 and rotating, a second pulley 52 fixed to a fixed shaft 440 of the valve 43 and rotating, and the first pulley ( 51 and the second pulley 52 is composed of a timing belt 53 wound between the drive shaft 30 is interlocked to continuously rotate the valve 43 in one direction.

The supply tank 41 temporarily stores the pressure of the working fluid generated by the booster pump 40 to supply it to the first cylinder 10 and the second cylinder 20 .

The recovery tank 42 is discharged from the supply tank 41 to generate power by the reciprocating means and the rotating means, and the recovered working fluid is temporarily stored so that it can be circulated to the booster pump 40 .

The valve 43 means a first discharge port 431 and a second discharge port 432 that are alternately opened and closed during rotation by penetrating in a direction crossing the outer circumferential surface of the cylindrical body at a predetermined distance, and crossing the outer circumferential surface of the cylindrical body a cylindrical valve having a first recovery port 433 and a second recovery port 434 to form the same opening/closing timing as the first discharge port 431 and the second discharge port 432 (43) consists of

That is, in the valve 43, the first discharge port 431 and the first recovery port 433 are formed in a direction parallel to each other, and the second discharge port 432 and the second recovery port 434 are the The first discharge port 431 and the first recovery port 433 are formed side by side in a direction perpendicular to each other and are rotatably fixed to the fixed shaft 440 .

This valve 43 is rotatably fixed to a fixed shaft 440 fixed horizontally to the fifth fixed bracket 715 and the sixth fixed bracket 716 fixed on the base 60 to provide a supply tank 41 . supplying the working fluid discharged from the to the plurality of first cylinders 10 and the second cylinder 20, and the working fluid discharged from the first cylinder 10 and the second cylinder 20 to the recovery tank 42 make it possible to recover

Accordingly, the first discharge port 431 and the second discharge port 432 have different opening and closing times, respectively, and the working fluid is simultaneously supplied to the first and second cylinders 20, so that the first cylinder 10 and the second 2 The first piston rod 111 and the second piston rod 211 of the cylinder 20 are supplied so that the forward and backward directions are alternated with each other, and the first and second recovery ports 434 are opened and closed at different times, respectively. The working fluid discharged from the first cylinder 10 and the second cylinder 20 can be introduced and circulated.

Specifically, the supply pipe (L1) formed on the outlet side of the supply tank (41) is branched into the supply pipe (L2) and another supply pipe (L3), and the supply pipe (L2) is the first discharge port of the valve (43) ( 431 , and the supply pipe L3 is connected to the second discharge port 432 of the valve 43 to supply the working fluid from the supply tank 41 .

A supply pipe (L4) is connected to the outlet side of the first discharge port (431), and a supply pipe (L5) is formed at the outlet side of the second discharge port (432) to supply the working fluid.

The supply pipe (L4) is branched into a supply pipe (L6) and a supply pipe (L7), the supply pipe (L6) is connected to the rear end of the first cylinder (10), the supply pipe (L7) is a continuous supply pipe (L8) to the second It is connected to the front end of the cylinder 20 so that the first piston rod 111 of the first cylinder 10 can be advanced, and the second piston rod 211 of the second cylinder 20 can be moved backward.

As the first piston rod 111 of the first cylinder 10 advances, the working fluid discharged to the tip of the first cylinder 10 is discharged to the supply pipe L9, and the second piston rod of the second cylinder 20 The working fluid discharged to the rear end of the second cylinder 20 while moving backward 211 is discharged to the supply pipe L9.

The supply pipe (L9) and the supply pipe (L10) are joined to the supply pipe (L11), the supply pipe (L11) is connected to the inlet side of the first recovery port (433).

On the other hand, the supply pipe (L5) formed on the outlet side of the second discharge port 432 is connected to open and close to the supply pipe (L11), and a supply pipe (L12) branching between the supply pipe (L7) and the supply pipe (L8) is formed, This supply pipe (L12) is connected to the inlet side of the first recovery port (433).

And, a supply pipe (L13) and a supply pipe (L14) are connected to the soccer side of the first recovery port (433) and the second recovery port (434), and the supply pipe (L13) and the supply pipe (L14) are joined to the supply pipe (L15) and the supply pipe L15 is connected to the recovery tank 42 to circulate the working fluid.

A process in which the present invention configured as described above is operated to generate power will be described.

First, initially, the booster pump 40 is driven to store a high-pressure working fluid in the supply tank 41 , and the first discharge port 431 of the valve 43 is opened and the supply pipe L2 and the supply pipe L4 are opened. ) forms a flow path, and the first recovery port 433 is opened so that the supply pipe L11 and the supply pipe L13 form a flow path. And the second discharge port 432 blocks the supply pipe (L3) and the supply pipe (L5) to close the flow path, and the second recovery port 434 blocks the supply pipe (L12) and the supply pipe (L14) to close the flow path, have.

In this state, the two first and second discharge ports 432 and the first and second recovery ports ( 434), the first discharge port 431 and the first recovery port 433 are formed in a direction parallel to each other, and the second discharge port 432 and the second recovery port 434 are the first discharge ports Since the port 431 and the first recovery port 433 are formed side by side in a direction perpendicular to each other, the first discharge port 431 and the first recovery port every time the continuously rotating valve 43 rotates by one quarter. 433 repeats opening and closing, and the second discharge port 432 repeats opening and closing with the second recovery port 434 to circulate and supply the working fluid.

Thereafter, the working fluid discharged from the supply tank 41 to the supply pipe L1 flows into the first discharge port 431 of the valve 43 forming a flow path through the supply pipe L2 and is discharged to the supply pipe L4. do.

At this time, since the flow path of the second discharge port 432 is closed in the supply pipe L3 branched from the supply pipe L1 together with the supply pipe L2 , the working fluid does not flow into the valve 43 .

The working fluid discharged from the supply pipe (L4) supplies the working fluid of the first cylinder 10 through the supply pipe (L6) branched from the supply pipe (L4), and the other supply pipe (L7) branched from the supply pipe (L4) and A supply pipe (L8) continuous to the supply pipe (L7) supplies the working fluid to the second cylinder (20). Since the working fluid flowing into the first chamber 112 at the rear end of the first cylinder 10 through the supply pipe L6 pushes the first piston 110 toward the second chamber 113, the first piston rod 111 advance the

In addition, since the working fluid flowing into the fourth chamber 213 at the tip of the second cylinder 20 through the supply pipes L7 and L8 pushes the second piston 210 toward the third chamber 212 , the second Reverse the piston rod (211).

As the first piston 110 and the second piston 210 move, the working fluid is discharged from the second chamber 113 of the first cylinder 10 and the fourth chamber 213 of the second cylinder 20 . .

The working fluid discharged from the second chamber 113 of the first cylinder 10 is discharged to the supply pipe L9, and the working fluid discharged from the fourth chamber 213 of the second cylinder 20 is the supply pipe L10. is emitted as

The working fluid discharged to the supply pipe (L9, l10) passes through the supply pipe (L11) to the first recovery port (433) of the valve (43) forming a flow path and the supply pipes (L13, L15) to the recovery tank (42) is sent, and the working fluid of the recovery tank 42 can be circulated by repeating the above-described process by the booster pump 40 .

The first rack 230 and the second moving together with the first piston rod 111 and the second piston rod 211 to move backward by the operation of the first cylinder 10 and the second cylinder 20 as described above. The second rack 240 rotates the first rack gear 231 and the second rack gear 241 , respectively, and the first rack gear 231 and the second rack gear 241 rotate the drive shaft 30 .

At this time, the first rack gear 231 and the second rack gear 241 rotate in opposite directions because the first rack 230 and the second rack 240 move in opposite directions alternately. Among the one-way clutches 250 and 251 provided in the gear 231 and the second rack gear 241 , one one-way clutches 250 and 251 are provided in the other one-way clutches 250 and 251 . and is installed in the opposite direction to rotate the drive shaft 30 in the same direction.

Thereafter, when the valve 43 continuously rotates by 1/4, the flow path is closed in the first discharge port 431 and the first recovery port 433 in which the flow path was opened, and the second flow path was closed. As for the discharge port 432 and the second recovery port 434 , the second discharge port 432 is connected to the supply pipe L3 and the supply pipe L5 to open a flow path, and the second recovery port 434 is connected to the supply pipe L12 ) and the supply pipe (L14) are connected to open the flow path.

Accordingly, the working fluid discharged from the supply tank 41 to the supply pipe L1 flows into the second discharge port 432 of the valve 43 forming a flow path through the supply pipe L3 and flows into the supply pipe L5. is emitted

At this time, since the flow path of the second discharge port 432 is closed in the supply pipe L2 branched from the supply pipe L1 together with the supply pipe L2 , the working fluid does not flow into the valve 43 .

The working fluid discharged to the supply pipe (L5) flows into the supply pipe (L11) to which the supply pipe (L5) is connected, and then through the supply pipes (L9, L10) connected to the supply pipe (L11) the first cylinder 10 and the second The working fluid is supplied to the cylinder 20, and the working fluid flowing into the second chamber 113 at the tip of the first cylinder 10 through the supply pipe L9 moves the first piston 110 into the first chamber 112. ) to push the first piston rod 111 backward.

In addition, since the working fluid flowing into the third chamber 212 at the rear end of the second cylinder 20 through the supply pipe L10 pushes the second piston 210 toward the fourth chamber 213 , the second piston rod (211) forward.

As the first piston 110 and the second piston 210 move, the working fluid is discharged from the first chamber 112 of the first cylinder 10 and the fourth chamber 213 of the second cylinder 20 . .

The working fluid discharged from the first chamber 112 of the first cylinder 10 is discharged to the supply pipe L6, and the working fluid discharged from the fourth chamber 213 of the second cylinder 20 is the supply pipe L1. is emitted as

The working fluid discharged to the supply pipes (L6, L11) goes through the supply pipe (L12) to the recovery tank (42) through the first recovery port (433) of the valve (43) and the supply pipes (L14, L15). is sent, and the working fluid of the recovery tank 42 can be circulated by repeating the above-described process by the booster pump 40 .

A first rack 230 that moves together with a first piston rod 111 that moves backward by the operation of the first cylinder 10 and the second cylinder 20 as described above, and a second piston rod 211 that advances and The second rack 240 moving together rotates the first rack gear 231 and the second rack gear 241, respectively, and the first rack gear 231 and the second rack gear 241 are the driving shafts 30. rotate the

At this time, the first rack gear 231 and the second rack gear 241 rotate in opposite directions because the first rack 230 and the second rack 240 are staggered and move in opposite directions. Among the one-way clutches 250 and 251 provided in the gear 231 and the second rack gear 241, one one-way clutch 250, 251 is provided in the other rack gear. As it is installed in the opposite direction to the drive shaft 30 continues to rotate in the same direction.

The circulation of the working fluid as described above includes the first pulley 51 fixed to the driving shaft 30 and rotating, the second pulley 52 fixed to the fixed shaft 440 of the valve 43 and rotating, and the first This is made possible by continuously rotating the valve 43 in one direction by a power transmission mechanism composed of a timing belt 53 wound between the pulley 51 and the second pulley 52 .

So far, the present invention has been focused on preferred embodiments.

The embodiments described in this specification and the configurations shown in the drawings relate to one most preferred embodiment of the present invention, and do not represent all of the technical spirit of the present invention, so various equivalents and modifications that can be substituted for them are It should be understood that there may be examples.

Therefore, the present invention is not limited to the presented embodiments, and within the equivalent scope of the technical spirit of the present invention and the technical spirit described in the claims to be described below by those of ordinary skill in the technical field to which the present invention pertains. There may be various modifications and changeable embodiments.

10: first cylinder
110: first piston 111: first piston rod
112: first chamber 113: second chamber
20: second cylinder
210: second piston 211: second piston rod
212: third chamber 213: fourth chamber
230: first rack 231: first rack gear
232: first guide rail 233: support
240: second rack 241: second rack gear
242: second guide rail 243: support ring
250, 251: One Way Clutch
30: drive shaft
40: booster pump
41: supply tank 42: recovery tank
43: valve 431: first outlet port
432: second discharge port 433: first return port
434: second recovery port 440: fixed shaft
51: first pulley 52: second pulley
53: timing belt
60: base
711: first fixing bracket 712: second fixing bracket
713: third fixing bracket 714: fourth fixing bracket
715: fifth fixing bracket 716: sixth fixing bracket
L1 ~ L15: supply pipe

Claims (7)

A power generating device capable of generating power with the pressure of gas or liquid, comprising:
At least one pair of reciprocating means operating at the same time in alternating directions;
Transmission means installed to correspond to the reciprocating means, converting the reciprocating motion of the reciprocating means into rotational motion, and converting means for reversing the rotational direction of the transmission means rotating in opposite directions by the reciprocating means with alternating traveling directions a rotation means for converting the linear motion generated by the reciprocating motion means into rotational motion in the same direction;
a drive shaft 30 rotating by the rotating means and supplying power to a load;
a working fluid supply means for supplying a working fluid selected from gas or liquid to drive the pair of reciprocating means;
a power transmission mechanism interlocking with the drive shaft 30 to continuously operate the working fluid supply means; provided,
The working fluid supply means is
a booster pump 40;
a supply tank 41 for storing the pressure of the working fluid generated by the booster pump 40;
a recovery tank 42 in which the working fluid discharged from the supply tank 41 to generate power and circulated to the booster pump 40 is stored;
The working fluid discharged from the supply tank 41 is supplied to the plurality of first and second cylinders 10 and 20, and the working fluid discharged from the first cylinder 10 and the second cylinder 20 is removed. a valve 43 means for supplying the recovery tank 42; including,
The valve 43 means,
At least two first and second discharge ports 431 and 432 and first and second recovery ports 433 and 434 that are alternately opened and closed during rotation by penetrating in a direction intersecting the outer circumferential surface of the cylindrical body at a predetermined distance while providing ,
The first discharge port 431 and the first recovery port 433 are formed in a direction parallel to each other,
The second discharge port 432 and the second recovery port 434 are formed parallel to each other in a direction perpendicular to the first discharge port 431 and the first recovery port 433 and rotate on the fixed shaft 440 . Consists of a cylindrical valve 43 that is fixed as possible,
The first and second discharge ports (431, 432) and the first and second recovery ports (433, 434) are connected to the first cylinder (10) and the second cylinder (20),
The first and second discharge ports 431 and 432 are,
The first and second piston rods 111 and the second piston rod of the first cylinder 10 and the second cylinder 20 are simultaneously supplied with the working fluid to the first and second cylinders 10 and 20 while different opening and closing times, respectively. (211) is supplied so that the forward and backward directions are alternated with each other,
The first and second recovery ports 433 and 434 are,
A power generating device using a working fluid, comprising allowing the working fluid discharged from the first cylinder 10 and the second cylinder 20 to be introduced and circulated while changing the opening/closing timing, respectively.
The method according to claim 1,
The reciprocating means is
At least a pair of the first cylinder 10 and the second cylinder 20 are arranged with different forward and backward traveling directions of the first piston rod 111 and the second piston rod 211,
A supply means for supplying a working fluid so that the first piston rod 111 and the second piston rod 211 of the first cylinder 10 and the second cylinder 20 operate in different forward and backward travel directions; Power generating device using a working fluid, characterized in that it further comprises.
The method according to claim 1,
The rotating means,
First and second racks 230 and 240 fixed to the first piston rod 111 of the first cylinder 10 and the second piston rod 211 of the second cylinder 20;
It includes a first rack gear 231 and a second rack gear 241 that are engaged with the first and second racks 230 and 240 and are fixed to the drive shaft 30 to rotate the drive shaft 30 . Power generating device using a working fluid, characterized in that.
delete The method according to claim 1,
The power transmission mechanism,
a first pulley 51 fixed to the drive shaft 30 and rotating; a second pulley 52 fixed to the fixed shaft 440 of the valve 43 and rotating;
Consists of a timing belt 53 wound between the first pulley 51 and the second pulley 52,
Power generating device using a working fluid, characterized in that the valve 43 is continuously rotated in one direction by interlocking with the drive shaft (30).
The method according to claim 1,
The conversion means,
A power generating device using a working fluid, including a one-way clutch (250, 251).
delete

Images