CN201526519U - Double-acting blade-type hydraulic transformer controlled by motor - Google Patents
Double-acting blade-type hydraulic transformer controlled by motor Download PDFInfo
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- CN201526519U CN201526519U CN200920028975XU CN200920028975U CN201526519U CN 201526519 U CN201526519 U CN 201526519U CN 200920028975X U CN200920028975X U CN 200920028975XU CN 200920028975 U CN200920028975 U CN 200920028975U CN 201526519 U CN201526519 U CN 201526519U
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Abstract
The utility model relates to a double-acting blade-type hydraulic transformer controlled by a motor, comprising a shell, a rotating shaft, a left end cover, thrust plates, stators, rotors, a right end cover, a gear, blades, a motor and the like. The double-acting blade-type hydraulic transformer controlled by the motor is characterized in that the centers of the rotors and the stators are fixed and coincident, the blades are radially arranged along the rotors, one rotor is matched and connected with the left half shaft of the rotating shaft by a spline, the other rotor is matched and connected with the right half shaft of the rotating shaft by a spline, an outer ring of one stator is manufactured into the form of a gear in a range of 150 degrees by taking the center of a long radius arc as a center, and the other stator and the gear form a gear drive pair; and the gear is installed on an output shaft of the motor installed on the shell, the thrust plates are installed on the rotating shaft and are tightly pressed on two side faces of the stators, and the left end cover and the right end cover are fixed on the shell by threaded bolts. The double-acting blade-type hydraulic transformer controlled by the motor has the advantage that the pressure of a constant-voltage network system can be regulated to any value in the range of variation of load pressure in a throttle loss-free mode and can be applied to medium-pressure and high-pressure hydraulic systems.
Description
(1) technical field
The utility model relates to a kind of hydraulic transformer, and specifically a kind of double-acting vane hydraulic transformer of Electric Machine Control belongs to mechanical field.
(2) background technique
Hydraulic transformer is meant a kind of hydraulic element of realizing the pressure conversion in hydraulic transmission.Hydraulic transformer can be converted to output hydraulic pressure energy under the another kind of pressure to the input hydraulic pressure under the setting pressure expeditiously, use it can realize multi-load mutual incoherent control in constant pressure network, also can make the energy reverse flow, not only can not have restriction loss ground and drive the straight line load, but also can the rotary driving load.
Existing hydraulic transformer all is plunger-type structure basically, its working pressure height, more than 20Mpa, range of flow is big, generally be used for high pressure, high-volume hydraulic system, in, use in the low-pressure hydraulic system, efficient is very low, and plunger hydraulic transformer device structure complexity, machining accuracy height, to the oil pollution sensitivity, oil strain required precision height, price are expensive, therefore make the application area of hydraulic transformer be subjected to very big restriction.
(3) summary of the invention
Technical assignment of the present utility model is at the deficiencies in the prior art, a kind of compact structure is provided, flow is even, noise is little, running accuracy is high and steady, can be applicable to the double-acting vane hydraulic transformer of the Electric Machine Control of mesohigh, middle pressure, low-pressure hydraulic system, to enrich the kind of hydraulic transformer, enlarge the application area of hydraulic transformer.
The technical scheme in the invention for solving the technical problem:
A kind of double-acting vane hydraulic transformer of Electric Machine Control mainly is made up of housing, running shaft, left end cap, thrust plate, stator, rotor, right end cap, gear, motor, blade etc.; The center of rotor and stator is fixing and overlaps, the width of rotor is slightly littler than the width of stator, rotor is installed in the stator, one end of blade is put into the blade groove of rotor, the other end contacts with inner surface of stator, blade is settled along rotor radial, a rotor cooperates connection by spline with the left half axle of running shaft, another rotor cooperates connection by spline with the right axle shaft of running shaft, the outer ring of a stator is to make gear forms in the 150 ° of scopes in center with semi major axis center of arc, stator and gear constitute gear driving pair, gear is installed on the output shaft of motor, and motor is installed on the housing, and thrust plate is installed on the running shaft, and be pressed on stator about on two sides, left end cap, right end cap is by being bolted on the housing.
The double-acting vane hydraulic transformer of a kind of Electric Machine Control of the present utility model compared with prior art, the beneficial effect that is produced is:
(1) the utility model can be adjusted into arbitrary value in the induced pressure excursion with the constant pressure network system pressure in the mode of no restriction loss.
(2) the utility model can be applicable in mesohigh, middle pressure, the mesolow hydraulic system, promptly more than the 7Mpa, in the hydraulic system below the 20Mpa, has enlarged the application area of hydraulic transformer, has enriched the kind of hydraulic transformer.
(3) the utility model volume is little, in light weight, rotary inertia is little, and control is convenient, is easy to realize accurate control, and control performance is good.
(4) the utility model can be exported energy to load, also can be from load to the accumulator recovered energy.
(4) description of drawings
Below in conjunction with drawings and Examples the utility model is further specified.
Fig. 1 is a structure diagram of the present utility model
Fig. 2 is an A-A view of the present utility model
Fig. 3 is a B-B view of the present utility model
Fig. 4 is a C-C view of the present utility model
Fig. 5 is a hydraulic fluid port Connecting format schematic representation of the present utility model
Fig. 6 is a transformation principle schematic of the present utility model
Among the figure: 1. housing, 2. running shaft, 3. left end cap, 4,7,8,11. thrust plates, 5,9. stator, 6,10. rotor, 12. right end caps, 13. gears, 14,15. blades, 16. motors
(5) embodiment
Explain below below in conjunction with drawings and Examples the utility model being done.
Shown in Fig. 1,2,3,4, the double-acting vane hydraulic transformer of a kind of Electric Machine Control described in the utility model mainly is made up of housing 1, running shaft 2, left end cap 3, thrust plate 4,7,8,11 and stator 5,9 and rotor 6,10 and right end cap 12, gear 13, motor 16, blade 14,15 etc.; The center of rotor 6 and stator 5 is fixing and overlaps, the width of rotor 6 is slightly littler than the width of stator 5, rotor 6 is installed in the stator 5, one end of blade 14 is put into the blade groove of rotor 6, the other end contacts with the internal surface of stator 5, and blade 14 is radially settled (being that laying angle is zero) along rotor 6, and rotor 6 cooperates connection by spline with the left half axle of running shaft 2, under the effect of constant pressure network system mesohigh oil, but 2 rotations of rotor 6 driven rotary axles; Stator 5 outer rings are to make gear forms in the 150 ° of scopes in center with semi major axis center of arc, stator 5 constitutes gear driving pair with gear 13, stator 5 clockwise or be rotated counterclockwise and carry out variable under the drive of motor 16, gear 13 is installed on the output shaft of motor 16, motor 16 is installed on the housing 3, thrust plate 4,7 is installed on the running shaft 2, and be pressed on stator 5 about on two sides; The center of rotor 10 and stator 9 also is fixing and overlaps, the width of rotor 10 is slightly littler than the width of stator 9, rotor 10 is installed in the stator 9, one end of blade 15 is put into the blade groove of rotor 10, the other end contacts with the internal surface of stator 9, blade 15 is radially settled along rotor 10, and thrust plate 8,11 is installed on the running shaft 2, and be pressed on stator 9 about on two sides; Rotor 10 cooperates connection by spline with the right axle shaft of running shaft 2, and left end cap 3, right end cap 12 are by being bolted on the housing 1.
But by composition variable parts 17 such as running shaft 2, rotor 6, stator 5, gear 13, blade 14, motor 16, thrust plates 4,7, but by composition variable parts 18 such as running shaft 2, rotor 10, stator 9, blade 15, thrust plates 8,11.The variable parts 17 of the double-acting vane hydraulic transformer of described a kind of Electric Machine Control and structure, the functional similarity of Double-action Vane Secondary Component, variable parts 17 can be seen a Double-action Vane Secondary Component as; The quantitative part 18 of the double-acting vane hydraulic transformer of described a kind of Electric Machine Control and structure, the functional similarity of quantitative double-action sliding-vane motor, quantitative part 18 can be seen a quantitative double-action sliding-vane motor as; So, the double-acting vane hydraulic transformer of described a kind of Electric Machine Control can be regarded as and formed by secondary component and fixed displacement motor coaxial rigid connection, as shown in Figure 5, the filler opening that the upper left hydraulic fluid port M of variable parts 17 is a kind of double-acting vane hydraulic transformer of Electric Machine Control, filler opening M is connected with the high-pressure oil passage of constant pressure network system, the oil outlet that the upper right hydraulic fluid port N of quantitative part 18 is a kind of double-acting vane hydraulic transformer of Electric Machine Control, oil outlet N is connected with load end, filler opening M is identical with oil outlet N size, the following hydraulic fluid port of variable parts 17 and the following hydraulic fluid port of quantitative part 18 link together, become hydraulic fluid port O of double-acting vane hydraulic transformer of a kind of Electric Machine Control, hydraulic fluid port O is connected with fuel tank, hydraulic fluid port O replenishes fluid to hydraulic transformer on the one hand, fluid with unnecessary fluid and hydraulic transformer internal leakage generation flows back to fuel tank on the other hand, and hydraulic fluid port O is greater than filler opening M and oil outlet N.
As shown in Figure 6, in the constant pressure network pressure p
1Effect under, the active torque that variable parts 17 produce is:
The drag torque that quantitative part 18 produces is:
In the formula: V
1, V
2Be the discharge capacity of variable parts 17, quantitative part 18, p
1, p
2Be the pressure of hydraulic transformer into and out of oil port, p
0Be the pressure at fuel tank place, common p
0=0.
Ignore the frictional resistance moment between variable parts 17 and the quantitative part 18, work as T
1+ T
2=0 o'clock, hydraulic transformer was in state of equilibrium, and this moment, hydraulic transformer into and out of the pressure ratio between the hydraulic fluid port was:
In the formula: λ is a transformation ratio.
By above derivation as can be seen, transformation ratio is the ratio of hydraulic transformer inlet/outlet pressure, and it also equals the inverse ratio of corresponding discharge capacity.Here pressure p
1Be the pressure of constant pressure network, it is a definite value, and pressure p
2Depend on that due to load, therefore the transformation of the double-acting vane hydraulic transformer of described a kind of Electric Machine Control comes down to regulate discharge capacity V
1/ V
2Value because the discharge capacity V of quantitative part 18
2Be a fixed value, so be discharge capacity V in the work by Moderator Variable parts 17
1Satisfy the needs of load variations.
When the double-acting vane hydraulic transformer of described a kind of Electric Machine Control is not worked, the equal transfixion of rotor of variable parts 17 and quantitative part 18, the stator of variable parts 17 is in initial rotational position (zero point), the discharge capacity V of variable parts 17
1Be zero, by formula (1) as can be known, transformation ratio λ equals zero.
During the work of the double-acting vane hydraulic transformer of described a kind of Electric Machine Control, for adapting to the variation of load, under the effect of motor, the stator of variable parts 17 clockwise or be rotated counterclockwise, along with the variation of stator angle of swing, the discharge capacity V of variable parts 17
1Also constantly change, by formula (1) as can be known, transformation ratio λ just changes thereupon, realizes transformation, satisfies the needs of load variations.
The size and Orientation of the stator angle of swing of the variable parts 17 of the double-acting vane hydraulic transformer of described a kind of Electric Machine Control is by the corner decision of motor (servomotor or stepping motor) output shaft, in the work, detect the corner of servomotor output shaft by angular displacement sensor, feed back to controller, send instruction by controller and give servomotor, control stator angle of swing (size and Orientation), or send to the umber of pulse of stepping motor by controller control, control the angle of swing (size and Orientation) of stator.
Claims (2)
1. the double-acting vane hydraulic transformer of an Electric Machine Control comprises housing (1), running shaft (2), left end cap (3), thrust plate (4,7,8,11), stator (5,9), rotor (6,10), right end cap (12), gear (13), blade (14,15), motor (16); It is characterized in that, the center of rotor (6) and stator (5) is fixing and overlaps, the width of rotor (6) is slightly littler than the width of stator (5), rotor (6) is installed in the stator (5), one end of blade (14) is put into the blade groove of rotor (6), the other end of blade (14) contacts with the internal surface of stator (5), blade (14) is radially settled along rotor (6), rotor (6) cooperates connection by spline with the left half axle of running shaft (2), stator (5) outer ring is to make gear forms in the 150 ° of scopes in center with semi major axis center of arc, stator (5) constitutes gear driving pair with gear (13), gear (13) is installed on the output shaft of motor (16), motor (16) is installed on the housing (3), thrust plate (4,7) be installed on the running shaft (2), and be pressed on stator (5) about on two sides; The center of rotor (10) and stator (9) also is fixing and overlaps, the width of rotor (10) is slightly littler than the width of stator (9), rotor (10) is installed in the stator (9), one end of blade (15) is put into the blade groove of rotor (10), the other end of blade (15) contacts with the internal surface of stator (9), blade (15) is radially settled along rotor (10), and thrust plate (8,11) is installed on the running shaft (2), and be pressed on stator (9) about on two sides; Rotor (10) cooperates connection by spline with the right axle shaft of running shaft (2), and left end cap (3), right end cap (12) are by being bolted on the housing (1); Upper left hydraulic fluid port is filler opening (M), filler opening (M) is connected with the high-pressure oil passage of constant pressure network system, upper right hydraulic fluid port is oil outlet (N), oil outlet (N) is connected with load end, following hydraulic fluid port is hydraulic fluid port (O), hydraulic fluid port (O) is connected with fuel tank, and filler opening (M) is identical with oil outlet (N) size, and hydraulic fluid port (O) is greater than filler opening (M) and oil outlet (N).
2. the double-acting vane hydraulic transformer of a kind of Electric Machine Control according to claim 1 is characterized in that, motor (16) is servomotor or stepping motor.
Priority Applications (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN200920028975XU CN201526519U (en) | 2009-07-09 | 2009-07-09 | Double-acting blade-type hydraulic transformer controlled by motor |
Applications Claiming Priority (1)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
CN200920028975XU CN201526519U (en) | 2009-07-09 | 2009-07-09 | Double-acting blade-type hydraulic transformer controlled by motor |
Publications (1)
Publication Number | Publication Date |
---|---|
CN201526519U true CN201526519U (en) | 2010-07-14 |
Family
ID=42517806
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
CN200920028975XU Expired - Fee Related CN201526519U (en) | 2009-07-09 | 2009-07-09 | Double-acting blade-type hydraulic transformer controlled by motor |
Country Status (1)
Country | Link |
---|---|
CN (1) | CN201526519U (en) |
-
2009
- 2009-07-09 CN CN200920028975XU patent/CN201526519U/en not_active Expired - Fee Related
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Legal Events
Date | Code | Title | Description |
---|---|---|---|
C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
C17 | Cessation of patent right | ||
CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20100714 Termination date: 20110709 |