TECHNICAL FIELD
The present invention relates, in general, to oscillating vane type pump actuators which realize a high power oscillating drive using high-pressure work oil as a power conversion means and, more particularly, to an improved high-pressure oscillating vane type pump actuator which can provide effective measures to solve problems caused in an apparatus which has proved the efficiency of the wave-power generation to be markedly enhanced using an oscillating vane type pump actuator that can be used in high pressure of 25 Mpa.
BACKGROUND ART
The inventor of the present invention has strived to develop wave-power generation systems having high energy efficiency from when he worked at the Muroran Industry College of Japan. In detail, it pertains to using wave power having two kinds of complex motion mechanisms including vertical and horizontal motions. An oscillating plate is installed at a singular point at which interference between incident waves and reflected waves occurs, particularly, at a singular point ![text missing or illegible when filed]()
(Application No. 2000-128632)
[Patent document 2] Japanese Patent No. 2002-168180 (Application No. 2000-403806)
Technical Solution
In order to accomplish the above object, the present invention is configured such that the lengths of opposite ends of a cylinder are shortened and a cylindrical part that protrudes towards the cylinder is provided on each side cover to make up for the shortened cylinder. Furthermore, at junction surfaces between a fixed vane and the side covers, to mitigate excessive pressure applied to the junction surfaces, a passage that always communicates with a low-pressure side working chamber is formed in the surface that is enclosed by a seal provided on a joined surface of the fixed vane that is joined to each side cover. Thus, the side covers and the fixed vane are put into contact with each other by oil films at pressures lower than that of the conventional technology, thereby allowing deformation attributable to a relative distortion direction difference.
Advantageous Effects
According to the present invention, the cylinder is shorter than that of the conventional technology, and a cylindrical part is provided on each side cover to make up for the shortened cylinder. Therefore, on the junction between the cylinder and the side covers that have different directional strengths and are coupled to each other by bolts or the like, even when high pressure applied into the working chamber causes ellipse-like distortion of the cylinder, the surfaces of the side covers that are joined to the cylinder are distorted in the same manner as that of the cylinder unlike the form of distortion of the side cover body, because the cylindrical part has the same shape as that of the cylinder. In the present invention, the relative distortion rate of the cylinder and the side covers can be limited to 20 μm to 30 μm, so that the fretting corrosion on the junction surfaces between them can be reliably prevented.
The same pressure can be maintained over the entire area of a contact surface between a fixed vane and the cylinder to which the fixed vane is fixed by a bolt or key, as well as contact surfaces between the fixed vane and the side covers, thanks to the use of a passage that communicates with the working chambers. In the passage, a check valve prevents a high-pressure side working chamber from communicating with the passage and allows a low-pressure side working chamber from communicating with the passage, so that a low pressure state can always be maintained, and the contact surfaces between the side covers and the fixed vane are brought contact with each other by a thin oil film. As a result, even if there is a difference in relative distortion between them, stress applied to the contact surfaces in the direction of the distortion is relatively low, thus preventing fretting corrosion that may be caused by fine oscillation between the elements that are strongly joined to each other.
DESCRIPTION OF DRAWINGS
FIG. 1 is a cross-sectional view showing a central portion of a conventional oscillating vane type pump actuator from in the axial direction.
FIG. 2 is a longitudinal sectional view showing the conventional oscillating vane type pump actuator.
FIG. 3 is a cross-sectional view showing a central portion of an oscillating vane type pump actuator from in the axial direction, according to the present invention.
FIG. 4 is a sectional view taken along line C-D of FIG. 3.
FIG. 5 is an enlarged front view showing a joining surface between a right side cover and a fixed vane of FIG. 4;
FIG. 6 is a bottom view of the fixed vane of FIG. 5 and partially shows a sectional view taken along line E-F of FIG. 5.
FIG. 7 is a side schematic view showing an example in which the present invention is used in a pendulum type wave-power generating apparatus which can generate power at high-efficiency.
FIG. 8 is a schematic view showing the wave-power generating apparatus of FIG. 7 from the left-right direction.
FIG. 9 is a schematic view showing an example in which the present invention is used in a rudder control device of a large ship.
DESCRIPTION OF THE REFERENCE NUMERALS IN THE DRAWINGS
1, 2: side cover of conventional oscillating vane type pump actuator
1
a,
2
a: bearing of oscillating shaft of conventional oscillating vane type pump actuator
1
d,
2
d: contact surface between side covers and a cylinder of a conventional oscillating vane type pump actuator
3: cylinder of conventional oscillating vane type pump actuator
4, 5: side cover/cylinder connection bolts of conventional oscillating vane type pump actuator
6: oscillating shaft of conventional oscillating vane type pump actuator
7: rotor of conventional oscillating vane type pump actuator
7
a,
7
b: oscillating vane of conventional oscillating vane type pump actuator
8: rotor shaft key of conventional oscillating vane type pump actuator
9
a,
9
b: fixed vane of conventional oscillating vane type pump actuator
10
a,
10
b: key for fixed vane of conventional oscillating vane type pump actuator
11
a,
11
b: a pair of working chambers connected to each other by a connection hole in a conventional oscillating vane type pump actuator
12
a,
12
b: another pair of working chambers connected to each other by a connection hole in a conventional oscillating vane type pump actuator
13, 14: pipes connecting working chambers that increase and reduce in volume in a hydraulic system in a conventional oscillating vane type pump actuator
15, 16: connection hole communicating interlocking working chambers with each other in a conventional oscillating vane type pump actuator
17, 18: contact surface between side cover and fixed vane of a conventional oscillating vane type pump actuator
1
c,
2
c: side cover of oscillating vane type pump actuator of the present invention
1
c-a, 2c-a: bearing of oscillating shaft of oscillating vane type pump actuator of the present invention
1
c-c, 2c-c: cylindrical part of side cover of oscillating vane type pump actuator of the present invention
1
c-d, 2c-d: contact surface between cylinder and cylindrical part of side cover of the present invention
3
c: cylinder of an oscillating vane type pump actuator of the present invention
4
c,
5
c: connection bolt of cylinder and side cover
6
c: oscillating shaft of an oscillating vane type pump actuator of the present invention
7
c: rotor of an oscillating vane type pump actuator of the present invention
7
c-a, 7c-b: oscillating vane of an oscillating vane type pump actuator of the present invention
8
c: rotor shaft key of the present invention
9
c-a, 9c-b: fixed vane of an oscillating vane type pump actuator of the present invention
10
c-a, 10c-b: key of fixed vane of the present invention
11
c-a, 11c-b: a pair of interlocking working chambers of an oscillating vane type pump actuator of the present invention
12
c-a, 12c-b: another pair of interlocking working chambers of an oscillating vane type pump actuator of the present invention
13
c,
14
c: pipes connecting working chambers that increase and reduce in volume in a hydraulic system according to the present invention
15
c,
16
c: connection hole communicating interlocking working chambers with each other according to the present invention
17
c,
18
c: contact surface between a side cover and fixed vane of the present invention
19
c-a, 19c-b: slide surface between a rotor and fixed vane of the present invention
20
c-a, 20c-b: contact surface between a cylinder and fixed vane of the present invention
21, 22: check valve provided in a fixed vane of the present invention
23: passage passing through opposite side surface of a fixed vane in contact with side covers according to the present invention
24: mounting bolt of a fixed vane
25: rotary seal
40
c-1, 40c-2: fixed seal provided between cylinder and a fixed vane according to the present invention
41
c-1, 41c-2, 41c-3: fixed seal provided on contact surface of side cover installed on a fixed vane according to the present invention
42
c-1, 42c-2: rotor slide seal provided on a fixed vane according to the present invention
43
c-1, 43c-2, 43c-3, 43c-4: fixed seal end pin of contact surface of a side cover of fixed vane according to the present invention
44
c-1, 44c-2: coil spring compressing fixed seal end pin of fixed vane according to the present invention
45, 46: connection pipe between oscillating vane pump and hydraulic system in example in which an oscillating vane type pump actuator of the present invention is used in a pendulum type wave-power generating apparatus
47: wave surface
48: pendulum plate receiving wave power in a pendulum type wave-power generating apparatus
49: oscillating shaft bearing of a pendulum type wave-power generating apparatus
50: oscillating vane pump of an example in which an oscillating vane type pump actuator of the present invention is used in wave-power generating apparatus
51: concrete caisson of a pendulum type wave-power generating apparatus
52: opening of caisson
53: fixed wall of caisson
54: spherical bearing of oscillating shaft of wave-power generating apparatus
55: bearing of oscillating shaft of wave-power generating apparatus
56, 56′: support rod connecting pendulum plate to oscillating shaft of pendulum type wave-power generating apparatus
60: actuator of example in which oscillating vane type pump actuator of the present invention is used to control rudder of large ship
61: main rudder shaft
62: rudder
BEST MODE
Hereinafter, the present invention will be described in detail with reference to the attached drawings.
FIG. 1 is a cross-sectional view showing a central portion of a conventional oscillating vane type pump actuator from in the axial direction. FIG. 2 is a sectional view taken along line A-B of FIG. 1. As shown in FIG. 1, an input/output shaft 6 is installed in the central portion of the oscillating vane type pump actuator. A rotor 7 is firmly fixed on the input/output shaft 6 by a key 8. A pair of oscillating vanes 7a and 7b are provided on the rotor 7 in a straight line and integrated with the rotor 7 so that sufficient coupling strength therebetween can be ensured. A pair of fixed vanes 9a and 9b are firmly fixed by keys 10a and 10b and bolts 24 to a cylinder 3 which encloses the oscillating vanes 7a and 7b. A working chamber which increases or reduces in volume comprises four chambers; two chambers are disposed at symmetrical positions on the center axis of the shaft 6 and maintain the same pressure and repeat an increase and reduction in the volume, thus providing the function as an oscillating vane type pump actuator. To achieve the above purpose, a pair of working chambers 11a and 11b which are disposed at symmetrical positions around the center axis communicate with each other through a connection hole 16. The other pair of working chambers 12a and 12b communicate with each other through a connection hole 15. The working chambers are connected to all portions of the hydraulic system by pipes 13 and 14 which are disposed around the installation position of the fixed vane 9b.
FIG. 2 is a longitudinal sectional view showing the oscillating vane type pump actuator. A pair of side covers 1 and 2 that have been pointed out as a problem are provided on opposite left and right ends of the actuator. The side covers 1 and 2 use bearings 1a and 2a to support the input/output shaft 6 of the oscillating vane type pump actuator at the centers thereof. The side covers 1 and 2 are firmly fixed by a plurality of fastening bolts 4 and 5 to the cylinder 3 disposed at the medial portion. FIG. 2 is a sectional taken along line A-B, wherein although the oscillating vane 7b has been shown at the left side of FIG. 1 and oriented in the horizontal direction, it is shown at the bottom side in FIG. 2. In the conventional oscillating vane type pump actuator having the above-mentioned basic construction, the cylinder 3 has high strength with respect to the axial direction, that is, the left-right direction of FIG. 2, and the side covers 1 and 2 have comparatively low strength with respect to the axial direction but have high strength with respect to the radial direction of the center axis. The most important problem is that the strength is comparatively low with respect to the radial direction of the center axis. Even if the plate of the cylinder 3 is thick enough to withstand a high pressure of 25 Mpa, the entire width of the cylinder 3 is relatively small, so that the radial strength of the cylinder 3 is comparatively low. Therefore, if the oscillating vane type pump actuator is used as a main device of a power conversion means of a pendulum type high efficiency wave-power generation apparatus, because pressure is applied in the radial direction to a pressure receiving surface of the cylinder 3 that defines the high-pressure working chambers, the cylinder 3 is distorted into an ellipse-like shape in which the diameter of a portion thereof is increased. When a pendulum plate is oscillated by wave power, the four working chambers repeatedly alternate between a high-pressure side and a low-pressure side, and the direction of the ellipse-like distortion also continuously varies as time goes by. Because the side covers 1 and 2 have low axial strength, they are deformed in a shape which is swollen outwards. Thereby, the side covers 1 and 2 are slightly reduced in diameter contrary to the cylinder 3 which is distorted into an ellipse-like shape. As a result, after the actuator has been operated for a long period of time, fretting corrosion occurs on a contact surface 17a between the side cover 1 and the fixed vanes 9a and 9b and on a contact surface 18a between the side cover 2 and the fixed vanes 9a and 9b. This is a problem that must be solved as soon as possible in order to commercialize the reasonable high-efficiency wave-power generation method that the inventor of the invention has striven to achieve for a long period of time. Although it has been thought that more firmly coupling the cylinder 3 to the side covers 1 and 2 that have high radial strength will restrict the ellipse-like distortion of the cylinder 3, even if the coupling force among them is enhanced by the bolts 4 and 5, only flanges of the cylinder 3 that protrude outwards from the circumferential outer surface of the cylinder are coupled to the side covers 1 and 2. Therefore, this method is not effective at restricting the distortion, which ranges from 200 μm to 300 μm, to within the target range of several μm or less.
FIG. 3 is a cross-sectional view showing the central portion of a fretting-corrosion-prevention oscillating vane type pump actuator from in the axial direction according to the present invention. The construction of the pump actuator of the present invention is almost the same as that of FIG. 1. An input/output shaft 6c that is disposed along the center axis of the oscillating vane type pump actuator is firmly coupled to a rotor 7c by a key 8. A pair of oscillating vanes 7c-b and 7c-a are provided on the rotor 7 in the horizontal direction and integrated with the rotor 7 to enhance the coupling strength therebetween. A cylinder 3c encloses the oscillating vanes 7c-b and 7c-a. A pair of fixed vanes 9a and 9b are fixed at upper and lower positions in the cylinder 3c by respective keys 10c-b and 10c-a and bolts. A working chamber which increases and reduces in volume comprises four chambers. Two chambers that are disposed at symmetrical positions on the center axis communicate with each other through a communication hole 15c, and the other two chambers communicate with a communication hole 16c, so that the chambers conduct the same volume variation operation. Pipes 14c and 13c are installed around the upper fixed vane 9c-b so that the working chambers are connected to a hydraulic system by the pipes 14c and 13c. FIG. 3 shows the cut line C-D to provide a sectional view for the sake of the following description of the present invention.
FIG. 4 is a sectional view taken along line C-D of FIG. 3. In the same manner as FIG. 2, FIG. 4 illustrates the oscillating vane 7c-b at the bottom side although it has been shown at the left side of FIG. 3 as being oriented in the horizontal direction. The most important characteristic of the present invention is that the lengths of the opposite left and right ends of the cylinder 3c are shortened, and a cylindrical part is provided on each of the left and right side cover 1c and 2c to compensate for the shortened cylinder, as shown in FIG. 4. In detail, a cylindrical part 1c-c that protrudes to the right is integrally provided on the left side cover 1c, and a cylindrical part 2c-c that protrudes to the left is integrally provided on the right side cover 2c. Each of the keys 10c-b and 10c-a that fix the fixed vanes 9c-b and 9c-a to the cylinder 3c has the same length as that of the cylinder 3c, and although it is shorter than that of the conventional art, there is no problem in terms of strength. The side covers 1c and 2c support the input/output shaft 6c using bearings 1c-a and 2c-a. A rotary seal 25 is also provided in the right side cover 2c to prevent oil from leaking out of the bearing 2c-a. The left and right side covers 1c and 2c are firmly coupled to the cylinder 3c by a plurality of bolts 4c and 5c. Each bolt 4c, 5c is longer than that of the conventional art by the length of the cylindrical part 1c-c, 2c-c of the corresponding side cover. The bolts 4c and 5c are preferably made of a material recently commercialized which has superior corrosion resistance against sea water.
In the oscillating vane type pump actuator of the present invention having the basic construction of FIG. 4, because the elements of the working chambers are firmly joined to each other under pressure, even if distortion is caused by high pressure of work oil that is periodically applied to the working chambers, fretting corrosion can be prevented by the elements that are oriented such that high-strength directions thereof are perpendicular to each other. In the present invention, the shapes of the joining surfaces of adjacent elements that are joined to each other under pressure are the same shape. Thus, even if the oscillation of the oscillating vanes 7c-b and 7c-a in the working chamber induces a slight ellipse-like distortion of the cylinder 3c, the cylindrical parts 1c-c and 2c-c that are provided on the side covers 1c and 2c have the same shape as that of the cylinder 3c so that they can restrict the distortion of the cylinder 3c. Therefore, if the lengths of the cylindrical parts 1c-c and 2c-c are set appropriately, it becomes easy to restrict the strain of distortion such that it is below 20 μm to 30 μm, thus coping with fretting corrosion. Further, in the conventional oscillating vane type pump actuator, fretting corrosion also occurs on the joining surfaces between the cylinder 3 and the side covers 1 and 2. However, in the present invention, positions of the portions that are strongly joined to each other by the bolts are spaced apart from each other by the length of the cylindrical parts 1c-c and 2c-2 of the side covers 1c and 2c. Therefore, if the axial length of the fixed vane is set to be slightly shorter than the distance between the side covers without having a mechanical coupling means, the pressure on the junction surfaces can be easily maintained at a lower pressure.
FIG. 5 is an enlarged right side view showing the joining surface between the side cover 2c and the fixed vane 9c-b to explain in detail the sealing structure of the fixed vane 9c-b. The fixed vane 9c-b has two kinds of seals including a seal interposed between fixed members and a seal provided on a slide surface of a slide member. In the former case, because there is no problem with abrasion of the seal, a seal which is made merely by cutting a large diameter O-ring to a predetermined size can exhibit sufficient sealing effect. A ‘V’-shaped seal groove and an O-ring type fixed seals 41c-1 and 41c-2 are provided around the perimeter of the fixed vane 9c-b. Fixed seals 40c-1 and 40c-2 are respectively provided around the perimeters of the contact surfaces between the cylinder 3c and the cylindrical part 1c-c and between the cylinder 3c and the cylindrical part 2c-c. Further, a seal groove is formed in the perimeter of the cylindrical rotor 7c in an approximately horizontal direction so that an O-ring type fixed seal 41-3 is seated into the seal groove. A hole having a diameter greater than the width of the seal groove is formed in the end of each fixed seal in the direction perpendicular to the contact surface, and cylindrical pins 43c-1, 43c-2, 43c-3 and 43c-4 supplement the ends of the fixed seals. Furthermore, perimeter grooves having lengths corresponding to the fixed vane 9c are axially formed in a slide surface 19c-b of the center shaft that is a surface in sliding contact with the rotor 7c. Slide seals 42c-1 and 42c-2 are provided in the respective perimeter grooves. Each of these opposite slide seals has a clamp shape (<), and each of the opposite ends thereof has a lip shape. The slide seal can conduct the role of the seal to counteract any pressure applied in the direction in which the angle of the clamp shape is increased, but if the pressure is applied thereto in the direction in which the angle is reduced, the slide seal allows work oil to flow from a high pressure side to a low pressure side. As shown in FIG. 5, each of the slide seals 42c-1 and 42c-2 is oriented such that when the pressure in the adjacent working chamber is high, the angle of the clamp shape is reduced. Thus, a high-pressure side working chamber can always communicate with the slide surface 19c-b between the fixed vane 9c-b and the rotor 7c.
Although the above-described seal structure of the fixed vane 9c-b is almost the same as that of Patent document 2, the present invention has a hydraulic pressure structure wherein the contact surface with the corresponding side cover always communicates with a low-pressure side working chamber, thus preventing excessive contact pressure from being applied to just one of the two sides. As shown by the dashed line of FIG. 5, a pair of check valves 21 and 22 are provided in the center of the fixed vane 9c-b that faces the left and right working chambers 12c-b and 11c-a. A passage 23, through which contact surfaces 17c and 18c between the fixed vane and the side covers communicate with each other, is formed through the fixed vane. Further, the passage 23 includes passages which communicate with the check valves 21 and 22. As shown in FIG. 5, space that is not completely sealed is formed between the slide seal 42c-1 and the pin 43c-1 which are close to each other and between the slide seal 42c-2 and the pin 43c-1 which are close to each other. Further, space between the pins 43c-1 and 43c-2 cannot be completely sealed. However, because the side cover 1c and 2c and the fixed vane 9c-b are assembled such that a distance between the fixed vane 9c-b and each side cover 1c, 2c is minimized, if leakage of oil through fine gaps is limited to a predetermined level or less, the oscillating vane type pump actuator can function as an actuator that can withstand even a pressure of 25 Mpa. Each cylindrical pin 43c-1, 43c-2, 43c-3, 43c-4 is made of metal, and the surface thereof is ground to an appropriate degree, so it functions as a seal similar to a piston seal. However, work oil that infiltrates into the contact surfaces 17c and 18c between the fixed vane 9c-b and the side coves through such incomplete seal portions flows out towards a low-pressure side working chamber 12c-b or 11c-b through the check valves 21 and 22, etc. Therefore, the flow rate of work oil in the contact surfaces that are enclosed by the seals provided on the fixed vane 9c-b can be maintained to the minimum flow rate.
FIG. 6 is a bottom view of the fixed vane 9c-b and partially shows a sectional view taken along line E-F of FIG. 5. Particularly, in FIG. 6, the pins 43c-1 and 43c-2 are clearly illustrated by the partially sectional view. Each pin 43c-1, 43c-2 has a short cylindrical shape. A pin hole that receives each pin is longer than the pin. Coil springs 44c-1 and 44c-2 are provided in the lower ends of the pin holes so that the corresponding pins are biased outwards. Compared to the entire length of the fixed vane 9c-b, the length of each pin hole is shorter than that of the fixed vane 9c-b. Thus, to minimize the area of portions which are not sealed by the fixed seals 41c-1 and 41c-3 and the pin 43c-1 or 43c-2, etc., it is preferable for the distance between the pins to be kept to the minimum. In detail, the distance between the pins can be kept within a range from 1.5 mm to 2 mm.
FIGS. 7 and 8 are schematic views showing an example of a high-efficiency pendulum type wave-power generation apparatus using the oscillating vane type pump actuator of the present invention.
As shown in the right side of FIG. 7, an opening 52 is formed in a portion of a concrete caisson 51 that faces the sea so that waves 47 can be guided into the caisson 51 by the opening 52. The left end of the caisson 51 is a fixed wall 53 which reflects waves that enter the caisson 51 from the right side. An incident wave that has been reflected by the fixed wall 53 becomes a reverse-directional reflected wave. As a result of interference between the incident waves and the reflected waves, a singular point, at which the wave height is always zero and horizontal kinetic energy is doubled, is formed at a position which is ¼ of the entire wave length. An oscillating shaft 49 of the pendulum plate 48 which receives wave-power is disposed at this singular point. An oscillating vane pump 50 that uses the present invention is integrally provided on one end of the oscillating shaft 49 to be used as the pump of a generator drive hydraulic system. Because most of the wave energy is applied in the horizontal direction to the vicinity of the pendulum plate 48, the wave power can be efficiently transmitted to the oscillating vane pump 50 via the oscillating shaft 49 and input to the hydraulic system in such a way that it is converted into rotary motion of the generator using high-pressure work oil that flows along pipes 45 and 46.
FIG. 8 is a schematic view illustrating the caisson of FIG. 7 in the direction from the fixed wall 35 towards the opening 52 so as to facilitate the understanding of the arrangement of the main elements of the apparatus. The width of the pendulum plate 48 is slightly less than that of the opening of the concrete caisson 51, and the pendulum plate 48 is attached to a pair of strong support rods 56 and 56′. The upper ends of the support rods 56 and 56′ are firmly fixed to the oscillating shaft 49. A pair of main bearings 54 are provided on the caisson 51 to support the oscillating shaft. The oscillating vane pump 50 of the present invention is integrally coupled to the left end of the oscillating shaft 49. The main bearing 54 comprises a spherical bearing having a comparatively large diameter, so that the site work of installing the main elements of the apparatus including the pendulum plate and the main shaft on the caisson 51 can be facilitated, thus reducing the working time.
FIG. 9 illustrates an example in which the oscillating vane type pump actuator of the present invention is used as an actuator for driving a steering device of a large ship. FIG. 9 is a sectional view of a lower portion of the stern of the ship. Because the space in the ship is limited and the actuator 60 for the rudder 62 requires a large amount of oscillating power, using the oscillating vane type pump actuator of the present invention as the actuator 60 can optimize the design of the peripheral elements. If the actuator 60 is directly connected to a main rudder shaft 61, regardless of the oscillating position of the rudder 62, the rate of variation in the flow rate of work oil always coincides with the rate of variation of the angle of the rudder 62. Further, the structure wherein the rudder 62 and the actuator 60 are directly connected to each other using the main rudder shaft 61 makes the responsivity between the rudder 62 and the actuator 60 superior. In addition, because the actuator is of high pressure of 25 Mpa, it realizes a very compact steering device, thus making better use of space in the ship, and being more economical. Even if a high-pressure hydraulic cylinder which is being sold in the market is used as the actuator, the flow rate of work oil that is required to change the angle of the rudder to a predetermined angle may become different, and because there is a difference in the volume of the working chamber between when manipulating the rudder in the clockwise direction and the counterclockwise direction, precise control of the pressure and flow rate is required, thus making a control system complex. Although advantages of the use of oscillating vane type pump actuators in steering devices have been well known and the expectations regarding commercialization have been high, a product having specifications for high-pressure has not been commercialized. If the oscillating vane type pump actuator of the present invention can lead to a low-cost mass production system, high economic effects resulting from exploitation of a new market are also expected. Moreover, in the hydraulic machine industry which has been reduced by the trend to favor energy-saving technology, a high power compact oscillating vane actuator for oscillation-driving a hinge unit of a large robot for high-rise work, which has not been able to be realized by the conventional technology, can be realized. Therefore the present invention can be a new technology which counteracts the shrinking of the market.
Patent Application
20120237384
