KR101044911B1 - Hydraulic angle controller of solar cell panel - Google Patents

Abstract

PURPOSE: A hydraulic type angle adjusting apparatus of a solar light generator is provided to automatically adjust inclined angle of a solar light generating module panel and minimizing the power consumption by using hydraulic power. CONSTITUTION: A lower installing stand(10) is formed at the upper side of the ground or the base concrete. The lower installing stand includes an anchor hole(16) which is combined with an anchor bolt. A circular recess(12a) is formed at the lower center part of the lower installing stand. A front-rear angle adjusting unit(30) adjusts the angle of a solar light generating module panel to the front and the rear directions using front-rear side hydraulic cylinders. A left-right angle adjusting unit(40) adjusts the angle of the solar light generating module panel to the left and the right directions using left-right side hydraulic cylinders(35, 36).

Description

Hydraulic angle controller of solar generator

The present invention relates to a hydraulic angle adjusting device of a solar generator, and more particularly, by using hydraulic pressure as the main power source rather than electric power, it is possible to automatically adjust the inclination angle of the photovoltaic module plate while minimizing the use ratio of power. The present invention relates to a hydraulic angle adjusting device for a photovoltaic generator that can maximize practical photovoltaic efficiency.

In general, construction of eco-friendly power generation facilities using solar, wind, and tidal power, which is a clean energy source that replaces fossil fuels but does not cause environmental pollution, is gradually increasing. Photovoltaic devices that generate electricity by arraying multiple solar cells that convert into energy are small enough to generate enough power to generate hot water for a household's daily use. Since it depends on the time and the angle of incidence of the solar power generation module plate, there is a problem that the conventional fixed solar power generation device does not improve the utilization efficiency of the solar light.

In order to solve this problem, the tracking type that tracks the position of the sun by using power so that the direct sunlight of the sun is incident vertically on the front surface of the photovoltaic module module is registered Korean Utility Model No. 297771, registered patent 0483291, Patent No. 0369897 and the like are many disclosed.

However, in the case of the power system, since some power is generated by the power required to operate the driving equipment, the increase in the amount of electricity generated by tracking the sunlight is less than the power consumption required to operate the driving equipment. There was a problem that can not improve the actual power generation efficiency.

The present invention is to solve the above problems, by using the hydraulic pressure as the main power source rather than the electric power while minimizing the use ratio of the power to minimize the tilt angle of the photovoltaic module plate, the actual solar power generation efficiency Its purpose is to provide a hydraulic angle adjusting device of the solar generator that can maximize the.

In order to achieve the above object, the present invention provides an angle adjusting device for a photovoltaic generator configured to adjust the inclination angle of the photovoltaic module according to the change in the altitude of the sun;

A rectangular plate body divided into upper and lower plates with anchor holes inserted into anchor bolts formed on an upper surface of a support or foundation concrete, and divided into upper and lower plates. A circular recess is formed at the center of the lower plate, and a circular recess is formed on the upper plate on the upper extension line of the circular recess. The through hole is formed through, the bottom of the circular recessed portion of the bottom plate and the top surface of the circular through hole is formed in the rear side recesses, while the side cross-section is formed in a rectangular shape, the circumferential pivot is formed in a circle in the plane, the back of the garden pivot The front end is formed with a recess toward the rear side, and the side cross section is formed into a semicircle to form a semicircle working recess forming a semicircle in the plane. The packing having a packing groove formed in the upper and lower plates adjacent to the upper surface of the recess and the semicircular operation recess And a hydraulic supply pipe which protrudes from one side and is connected to the right end surface of the semicircular operation recess, and receives a signal which varies according to the position trajectory of the sun, and selectively operates the hydraulic motor by a preset program accordingly. A lower mounting unit formed to separate the controller for transmitting hydraulic pressure into the hydraulic supply pipe through the hydraulic cylinder;

The circular recess of the upper and lower plates of the lower mounting plate is a flat plate that is circular in shape and has a circular support protrusion protruding to the outside at the outer periphery so as to correspond to the garden pivot, and the outer end of the circular support protrusion. The side of the furnace protrudes into a semi-circular plate body, which is positioned to correspond to the semi-circular operation recess, and the packing is vertically mounted at the center of the front end surface to form a piston protrusion for rotating the body by the hydraulic pressure introduced into the semi-circular operation recess through the hydraulic supply pipe. A shaft support is formed in the center of the upper surface with a rod that is vertically erected upwards. Packing grooves corresponding to the packing grooves are formed on the upper and lower surfaces of the parts, respectively. The front and rear prevention boards are formed to extend horizontally to the front and rear side separately from the upper surface of the plate, and are fixed to the upper surface of the front and rear prevention boards, respectively, and are vertically erected vertically upward. The piston rod, which is stretched by hydraulic pressure, protrudes upward from the surface, and the front and rear hydraulic cylinders having rollers pivoted by the roller shaft are formed on the piston rod upper surface, respectively, and are operated on the outer surface of the disc body for smooth rotation and sealing. A rotation disc which is injected with oil and rotated in the semicircular operation recess by hydraulic pressure;

Shaft yaw portion is formed in the bottom of the main body of the shaft support is inserted into the upper end of the shaft support flows to the front and rear sides, left and right shaft holes are formed on the left and right sides of the shaft yaw to the rotation axis is rotatably coupled on the shaft hole extension line of the shaft support. , Horizontally extending from the center of the body to the front and rear sides, respectively, and the front and rear horizontal bands are formed on the rollers of the front and rear hydraulic cylinders, respectively, and horizontally extending from the center of the body to the left and right horizontal bands, respectively. The vertically standing rod has a hydraulic supply pipe at the bottom, and a piston rod, which is stretched by hydraulic pressure, is projected upward on the upper surface, and left and right hydraulic cylinders each having a roller pivoted by a roller shaft are formed on the upper surface of the piston rod. Vertical standing up and down on the front and rear sides of the center A front and rear angle adjusting device having front and rear side engaging protrusions each having a joining line on the joists, and being angled back and forth by front and rear hydraulic cylinders operated and controlled by the controller;

The lower end is located between the front and rear side engaging protrusions and has a vertical hole that is vertically erected upwardly with a fitting hole axially coupled by the shaft bar on the coupling hole extension line. Horizontal poles are formed on the upper side of the roller, and horizontal left and right ends of the horizontal pole are horizontally extended to the front and rear sides, respectively, and the left and right module holders having fastening holes for fastening and fixing the solar power module plates are respectively formed. There is a feature that comprises a left and right angle adjusting device for angle adjustment of the photovoltaic module plate to the left and right.

As such, the present invention can automatically adjust the inclination angle of the photovoltaic module plate while minimizing the use ratio of power by using hydraulic pressure as the main power source rather than power, thereby maximizing the actual photovoltaic power generation efficiency. have.

The present invention is not limited to the above-described specific preferred embodiments, and various modifications can be made by those skilled in the art without departing from the gist of the present invention as claimed in the claims. Of course, such changes will fall within the scope of the claims.

1 is an exploded perspective view showing a fastening view of the hydraulic angle adjusting device of the solar generator according to the present invention embodiment,
Figure 2 is a perspective view showing a coupling of the hydraulic angle adjusting device of the solar generator according to the embodiment of the present invention,
3 is a front view of a state in which the front and rear side hydraulic cylinder of the hydraulic angle adjusting device of the solar generator according to the embodiment of the present invention is operated to adjust the front and rear side angles,
4 is a side view of a state in which the left and right hydraulic cylinders of the hydraulic angle adjusting device of the solar generator according to the embodiment of the present invention are operated to adjust the left and right angles;
Figure 5 is a plan view showing a rotating disc seated on the lower plate of the lower mounting of the hydraulic angle adjusting device of the solar generator according to the embodiment of the present invention.

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

1 is an exploded perspective view showing a fastening view of the hydraulic angle adjusting device of the solar generator according to the embodiment of the present invention, Figure 2 is a combined perspective view showing a fastening view of the hydraulic angle adjusting device of the solar generator according to the embodiment of the present invention, Figure 3 4 is a front view showing a state in which the front and rear hydraulic cylinders of the hydraulic angle adjusting device of the solar generator according to the present invention is operated to adjust the front and rear side angles, and FIG. 4 is a hydraulic angle adjusting device of the solar generator according to the embodiment of the present invention. The left and right hydraulic cylinder is operated to show a state in which the left and right angle adjustment is a state of use, Figure 5 is a plan view showing a rotating disc seated on the lower plate of the lower mounting of the hydraulic angle adjusting device of the solar generator according to the embodiment of the present invention.

For reference, in describing the present invention, when it is determined that a detailed description of a related known function or configuration may unnecessarily obscure the gist of the present invention, the detailed description thereof is omitted.

In addition, terms to be described below are terms defined in consideration of functions in the present invention, which may vary according to the intention or convention of a user or an operator.

Therefore, the definition should be made based on the contents throughout the specification.

The hydraulic angle adjusting device of the solar generator of the present invention is a device that can adjust the inclination angle of the photovoltaic module plate 50 in accordance with the change in the altitude of the sun, the lower mounting base 10 is fixed to the support or foundation concrete 10 And, by the hydraulic disk 20 in the semicircle operating recesses 11c and 12c by hydraulic pressure inside the lower mounting table 10, and the front and rear hydraulic cylinders 17 and 18 of the lower mounting table 10 to the front and rear sides. It consists of the left and right angle control knob 40, which is angle-controlled by the left and right hydraulic cylinders (35, 36) of the front and rear angle control mechanism (30) to be adjusted angle.

The lower mounting table 10 is a rectangular plate body divided into upper and lower plates 11 and 12, each having an anchor hole 16 inserted into and fixed to an anchor bolt formed on an upper surface of a support or a foundation concrete, and having a center of the lower plate 12. A circular recess 12a having a flat surface is formed therein, and a circular through hole 11a is formed in the upper plate 11 on the upper extension line of the circular recess 12a, and the circular recess 12a of the lower plate 12 is formed. A circular recess 11a of the upper plate 11 is formed in the center of the front end face of the front end, and the lateral pivots 11b and 12b are formed in a flat shape while the side cross sections are formed in a rectangular shape. 11b, 12b) The rear end face is formed with a recess toward the rear side, and the semicircular operation recesses 11c and 12c constituting a semicircle in the plane are respectively formed while the side cross section is formed into a semicircle, and the circular through hole 11a of the upper plate 11 is formed. ) Inner circumference and quorum pivot (11b, 12b) bottom and bottom plate (12) The upper and lower plates 11 and 12 adjacent to the circular cross section 12a of the side surface and the circumferential pivot 11b and 12b and the semicircular operation recesses 11c and 12c are respectively formed with packing grooves 11d and 11e formed inwardly. 11f) packings 13, 13a, 13b, 13c, and 13d having 12d, 12e, and 12f, respectively, are formed and protrude from one side to be connected to the right end surfaces of the semicircular operation recesses 11c and 12c. The supply pipe 14 is formed, receives a signal that is changed according to the position trajectory of the sun, and operates the hydraulic motor 15a by a preset program accordingly to selectively enter the hydraulic supply pipe 14 through the hydraulic cylinder 14a. The controller 15 for transmitting the hydraulic pressure is formed to be spaced apart.

The rotating disk 20 is a plate body having a circular surface that is seated in the circular through hole (11a) and the circular recessed portion (12a) of the upper and lower plates (11, 12) of the lower mounting table 10, protrudes to the outer periphery The circular support protrusions 21 are formed to correspond to the circumferential swing portions 11b and 12b, and the semi-circular operation recesses 11c, which protrude from the distal end faces of the circular support protrusions 21 to the outside in a semicircular plate body. 12c) and a piston projection 22 which rotates the body by the hydraulic pressure introduced into the semicircular operation recesses 11c and 12c through the hydraulic pressure supply pipe 14 so that the packing 22a is vertically mounted at the center of the front end face thereof. ) Is formed, the center of the body upper surface is a rod vertically erected upright, the upper end has a shaft hole (23a) and the upper surface of the shaft hole (23a) on the upper surface of the rotating trajectory surface of the semi-circular shape forming a rotational trajectory based on the shaft hole (23a) ( A shaft support 23 having a 23b) is formed, the outer periphery of the disc body and the circular Packing grooves 24a, 24b, 24c and 24d corresponding to the packing grooves 11e and 11f and 12e and 12f are formed on the upper and lower surfaces of the protrusions 21, respectively. The front and rear prevention boards 27 and 27a are formed to extend horizontally to the front and rear sides separately from the upper surface, and the hydraulic supply pipe 25d, which is fixed to the upper surface of the front and rear prevention boards 27 and 27a, respectively, is vertically erected upwardly. The piston rods 25a, 26a, which are respectively stretched by hydraulic pressure, are projected upward on the upper surfaces thereof, respectively, and the rollers pivoted on the upper surfaces of the piston rods 25a, 26a, respectively, by roller shafts 25b, 26b. Front and rear hydraulic cylinders (25, 26) having (25c, 26c) are formed, respectively, the operating oil is injected into the outer surface of the disc body for smooth rotation and sealing, the hydraulic pressure within the semi-circular operating recess (11c, 12c) Is rotated.

The front and rear angle adjusting device 30, the shaft support portion 23 is inserted into the upper end of the shaft support 23 of the rotation disc 20 is formed in the bottom of the body center, the shaft yaw portion 31 is formed to flow in the front and rear sides, the shaft yaw portion 31 on the left and right sides The left and right shaft holes 32 and 32a are pivotally coupled to the pivot shaft 23b on the extension line of the shaft support 23a. The horizontal hydraulic cylinders 32 and 32a are horizontally extended from the center of the body to the front and rear sides, respectively. Front and rear horizontal stages 33 and 33a are respectively formed above the rollers 17c and 18c of the 17 and 18, respectively, and left and right horizontal stages 34 and 34a are respectively extended horizontally from the center of the body to the left and right sides. The upper and lower piston rods 35a and 36a are hydraulic rods 35d and 36d respectively, and the upper and lower piston rods 35a and 36a are vertically erected upright from the left and right upper surfaces of the left and right horizontal stages 34 and 34a. To the upper end of the piston rod (35a, 36a) Left and right hydraulic cylinders 35 and 36 having rollers 35b and 36b pivoted by 5c and 36c, respectively, are formed, respectively, and are vertically erected upwards at the front and rear sides of the upper surface of the center of the body, and engaging holes 37a and 38a on the same extension line. The front and rear side coupling protrusions 37 and 38 each having a) are angled to the front and rear side by the front and rear hydraulic cylinders 17 and 18 which are operated and controlled by the controller 15.

The left and right angle control opening 40, the lower end is located between the front and rear side coupling protrusions (37, 38) and the fitting hole (41a) is axially coupled by the shaft bar (41b) on the extension line of the coupling holes (37a, 38a) The vertical stand 41 is formed to be vertically erected upwardly, and the horizontal stand is extended horizontally to the left and right sides at the upper end of the vertical stand 41, respectively, which is positioned above the rollers 35b and 36b of the left and right hydraulic cylinders 35 and 36. Pole 42 is formed, the horizontal pole 42 on the left and right ends of the horizontal extension to the front and rear side respectively, the left and right module holder 43 having fastening holes (43a, 44a) for fastening and fixing the photovoltaic module plate 50, respectively 44 are formed respectively to adjust the photovoltaic module plate 50 to the left and right by the left and right hydraulic cylinders 35 and 36 which are operated and controlled by the controller 15.

The present invention as described above, when the sun is located at a predetermined position according to the rule of the sun, the controller detects the hydraulic pressure generated through the hydraulic motor (15a) connected to the hydraulic supply pipe 14 of the lower mounting table 10 Adjusting the angle of the photovoltaic module 50 fixedly installed to the left and right angle control holes 40 by introducing an appropriate amount of hydraulic pressure into the cylinder 14a or the front and rear hydraulic cylinders 17 and 18 and the left and right hydraulic cylinders 35 and 36. By maximizing the angle of incidence, the power generation capacity and power generation capacity are maximized.

That is, when the hydraulic pressure of the hydraulic motor 15a is introduced into the hydraulic cylinder 14a by the controller 15, the hydraulic pressure is introduced into the semicircular operation recesses 11c and 12c of the lower mounting table 10 through the hydraulic supply pipe 14. While being pushed in, the piston protrusion 22 is rotated counterclockwise from the inside of the semicircular operation recesses 11c and 12c, and the front and rear hydraulic cylinders 25 and 26 and the front and rear angle adjusters 30 also rotate clockwise or counterclockwise. Let's go.

In addition, when the hydraulic pressure of the hydraulic motor 15a is introduced into the hydraulic supply pipes 25d and 26d of the front and rear hydraulic cylinders 25 and 26 by the controller 15, the piston rods 25a and 26a are selectively stretched and the front and rear angles are also increased. The adjuster 30 is angled in the front and rear side.

In addition, when the hydraulic pressure of the hydraulic motor 15a is introduced into the hydraulic supply pipes 25d and 26d of the left and right hydraulic cylinders 35 and 36 by the controller 15, the piston rods 35a and 36a are selectively stretched and the left and right angles are adjusted. Adjusting the angle 40 to the left and right side to adjust the angle of the upper side photovoltaic module plate 50 appropriately.

10: lower mounting table 11: top plate
11a: circular through hole 11b, 12b: garden swing
11c, 12c: Semicircle operating recess 11d, 11e, 11f, 12d, 12e, 12f: Packing groove
12: lower plate 12a: circular recess
13,13a, 13b, 13c, 13d: Packing 14: Hydraulic Supply Pipe
14a: hydraulic cylinder 15: controller
15a: controller 16: anchor ball
20: rotating disc 21: circular support protrusion
22: piston protrusion 22a: packing
23: shaft support 23a: shaft hole
23b: Rotating track surface 24a, 24b, 24c, 24d: Packing groove
25, 26: Front and rear hydraulic cylinders 25a, 25a: Piston rod
25b, 26b: roller shaft 25c, 26c: roller
25d, 26d: Hydraulic supply pipe 27,27a: Front and rear prevention board
30: front and rear angle adjusting device 31: shaft recess
32,32a: left and right shaft hole 32b: rotating shaft
33,33a: Front and rear horizontal band 34,34a: Left and right horizontal band
35, 36: left and right hydraulic cylinders 35a, 36a: piston rod
35b, 36b: Roller 35c, 36c: Roller Shaft
35d, 36d: Hydraulic supply pipe 37,38: Front and rear coupling protrusion
37a, 38a: Combined hole
40: left and right angle adjusting device 41: vertical stand
41a: fitting hole 42: horizontal pole
43,44: left and right module fixing stand 43a, 44a: fastening hole
50: solar power module

Claims (1)

A lower mount 10 formed on an upper surface of the support or the foundation concrete; A front and rear angle adjusting device 30 for angle-adjusting the photovoltaic module plate by the front and rear hydraulic cylinders 17 and 18; The left and right hydraulic cylinders 35 and 36 are provided with left and right angle adjusting holes 40 for adjusting the photovoltaic module plate to the left and right sides, and configured to adjust the inclination angle of the photovoltaic module plate according to the change in the sun's altitude. In the angle adjusting device of the solar generator;
The lower mounting table 10 is a rectangular plate body divided into upper and lower plates 11 and 12, each having an anchor hole 16 inserted into and fixed to an anchor bolt formed on an upper surface of a support or a foundation concrete, and having a center of the lower plate 12. A circular recess 12a having a flat surface is formed therein, and a circular through hole 11a is formed in the upper plate 11 on the upper extension line of the circular recess 12a, and the circular recess 12a of the lower plate 12 is formed. A circular recess 11a of the upper plate 11 is formed in the center of the front end face of the front end, and the lateral pivots 11b and 12b are formed in a flat shape while the side cross sections are formed in a rectangular shape. 11b, 12b) The rear end face is formed with a recess toward the rear side, and the semicircular operation recesses 11c and 12c constituting a semicircle in the plane are respectively formed while the side cross section is formed into a semicircle, and the circular through hole 11a of the upper plate 11 is formed. ) Inner circumference and quorum pivot (11b, 12b) bottom and bottom plate (12) The upper and lower plates 11 and 12 adjacent to the circular cross section 12a of the side surface and the circumferential pivot 11b and 12b and the semicircular operation recesses 11c and 12c are respectively formed with packing grooves 11d and 11e formed inwardly. 11f) packings 13, 13a, 13b, 13c, and 13d having 12d, 12e, and 12f, respectively, are formed and protrude from one side to be connected to the right end surfaces of the semicircular operation recesses 11c and 12c. The supply pipe 14 is formed, receives a signal that is changed according to the position trajectory of the sun, and operates the hydraulic motor 15a by a preset program accordingly to selectively enter the hydraulic supply pipe 14 through the hydraulic cylinder 14a. Controller 15 for transmitting the hydraulic pressure is formed spaced apart;
The circular plate 11a and the circular recess 12a of the upper and lower plates 11 and 12 of the lower mounting table 10 have a circular flat plate body. The outer periphery protrudes to the outside and the circumferential pivot portion 11b and 12b. The circular support protrusion 21 is formed to correspond to the side is formed, the side surface protrudes from the front end surface of the circular support protrusion 21 to the semi-circular plate body is located corresponding to the semi-circular operation recess (11c, 12c) At the center of the cross section, a packing 22a is vertically mounted, and a piston protrusion 22 is formed to rotate the body by hydraulic pressure introduced into the semicircular operation recesses 11c and 12c through the hydraulic supply pipe 14. The shaft support 23 has a shaft hole (23a) in the upper end with a rod vertically erected to the upper end, and a rotational track surface (23b) having a semicircular shape that forms a rotational track based on the shaft hole (23a) on the upper surface of the upper portion of the shaft hole (23a). ) Is formed, and the upper and lower surfaces of the disc body outer peripheral edge and the circular support protrusion 21 The packing grooves 24a, 24b, 24c, and 24d corresponding to the packing grooves 11e and 11f and 12e and 12f, respectively, are formed in the front and rear sides of the body upper surface 11, respectively. The front and rear prevention boards 27 and 27a extending to the side are formed horizontally, and are fixed to the upper surface of the front and rear prevention boards 27 and 27a, respectively, and have hydraulic rods 25d and 26d at the lower sides thereof. The piston rods 25a and 26a, which are stretched and contracted by hydraulic pressure, respectively protrude upwards, and the upper surfaces of the piston rods 25a and 26a have rollers 25c and 26c which are axially rotated by roller shafts 25b and 26b, respectively. The front and rear hydraulic cylinders 25 and 26 are formed, respectively, and the rotational disk 20 rotated in the semi-circular operation recesses 11c and 12c by hydraulic pressure by inserting working oil into the outer surface of the disc body for smooth rotation and sealing. and;
The front and rear angle adjusting device 30, the shaft support portion 23 is inserted into the upper end of the shaft support 23 of the rotation disc 20 is formed in the bottom of the body center, the shaft yaw portion 31 is formed to flow in the front and rear sides, the shaft yaw portion 31 on the left and right sides The left and right shaft holes 32 and 32a are pivotally coupled to the pivot shaft 23b on the extension line of the shaft support 23a. The horizontal hydraulic cylinders 32 and 32a are horizontally extended from the center of the body to the front and rear sides, respectively. Front and rear horizontal stages 33 and 33a are respectively formed above the rollers 17c and 18c of the 17 and 18, respectively, and left and right horizontal stages 34 and 34a are respectively extended horizontally from the center of the body to the left and right sides. The upper and lower piston rods 35a and 36a are hydraulic rods 35d and 36d respectively, and the upper and lower piston rods 35a and 36a are vertically erected upright from the left and right upper surfaces of the left and right horizontal stages 34 and 34a. To the upper end of the piston rod (35a, 36a) Left and right hydraulic cylinders 35 and 36 having rollers 35b and 36b pivoted by 5c and 36c, respectively, are formed, respectively, and are vertically erected upwards at the front and rear sides of the upper surface of the center of the body, and engaging holes 37a and 38a on the same extension line. Front and rear coupling protrusions (37, 38) each having a) is angled forward and backward by the front and rear hydraulic cylinders (17, 18) which are operated and controlled by the controller (15);
The left and right angle control opening 40, the lower end is located between the front and rear side coupling protrusions (37, 38) and the fitting hole (41a) is axially coupled by the shaft bar (41b) on the extension line of the coupling holes (37a, 38a) The vertical stand 41 is formed to be vertically erected upwardly, and the horizontal stand is extended horizontally to the left and right sides at the upper end of the vertical stand 41, respectively, which is positioned above the rollers 35b and 36b of the left and right hydraulic cylinders 35 and 36, respectively. Pole 42 is formed, the horizontal pole 42 on the left and right ends of the horizontal extension to the front and rear side respectively, the left and right module holder 43 having fastening holes (43a, 44a) for fastening and fixing the photovoltaic module plate 50, respectively 44 are formed, respectively, the hydraulic angle adjustment of the photovoltaic generator, characterized in that for adjusting the angle of the photovoltaic module plate 50 to the left and right by the left and right hydraulic cylinders (35, 36) that are operated and controlled by the controller (15). Device.

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