KR101594698B1 - A pumping type axial flow pump - Google Patents

Abstract

The present invention relates to a pumping type vertical screw pump. The present invention comprises a pumping operating means enabling a pump housing, a screw, and an operating unit to be vertically arranged, enabling the operating unit to be provided at the lowermost side, and enabling the screw to reciprocate to provide a virtual piston. Moreover, the present invention has a simple structure, is easily manufactured, and saves production costs. In addition, the present invention enables the pump housing, the screw, and the operating unit to be vertically arranged and enables the operating unit to be provided at the lowermost side in order to enhance convenience of maintenance.

Description

[0001] The present invention relates to a pumping type axial flow pump,

The present invention relates to a pumping operation type vertical screw pump, and more particularly, to a screw pump in which a pump housing, a screw and a driving unit are vertically arranged, a driving unit is provided at the lowermost position, The suction force and the grounding output are improved by the volumetric pumping operation by the virtual piston formed by the reciprocating motion of the screw together with the rotation by the screw. In addition, the self-absorption is smooth and the length of the screw is minimized, So as to minimize the damage of the installation object.

In general, a pump is one that imparts transferring energy to the fluid in a transportable manner.

Such pumps include a piston pump, an axial flow pump, a centrifugal flow pump, a gear pump, a vane puff, and a rotary pump.

The axial flow pump includes an impeller pump having a plurality of blades at equal intervals around a pump axis, and a screw pump provided on the outer surface of the pump shaft so as to have spiral wings continuously.

The impeller pump includes a cylindrical pump housing and an impeller housed in the pump housing. The impeller pump transports the object to be conveyed inside the pump housing by lifting force generated by wings provided on the pump shaft.

The screw pump is composed of a cylindrical pump housing and a screw housed in the pump housing, and the object to be conveyed is pushed by the wings formed in a spiral shape on the outer periphery of the pump shaft.

However, the above-mentioned conventional screw pump has a problem that the suction force is weak and the self-excitation is not easy and the discharge pressure is weak because the conveying object is conveyed by the rotation of the vane provided on the pump shaft.

Particularly, there has been a problem that it is impossible to carry out the self-excitation of the conveying object made of the particulate material.

In addition, the conventional screw pump has a problem in that it is not easy to transfer a conveyed object having a foreign object or a conveyed object having a length.

In addition, the conventional screw pump has a problem in that the screw is formed to be long since the screw must be formed to the destination at the time of transferring the object to be conveyed, the structure is complicated, the production is not easy, and the production cost is increased.

That is, the screw pump of the related art has a problem that the object to be conveyed can be transferred to the target point if the screw is formed at 10 m when the object is conveyed by 10 m.

In addition, since the conventional screw pump damages and installs the deck of the ship when installed on a ship, the installation thereof is not easy and the maintenance deck has to be damaged.

Korean Patent Publication No. 1994-0021940

Accordingly, it is an object of the present invention to provide a screw pump in which the conventional screw pump has poor suction and discharge pressures and is not easily sucked and difficult to transfer a conveyed object having a foreign object or a conveyed object having the same length, Since the screw must be formed to the destination at the time of transferring, the screw is long, the structure is complicated, the production is not easy, the production cost is increased, and the installation surface of the screw pump is damaged, In order to solve the problem.

That is, in the screw pump of the present invention, the pump housing, the screw and the driving unit are vertically arranged, the driving unit is formed at the lowermost position, and the screw is reciprocated to form a virtual piston which performs a volumetric pumping operation .

Therefore, according to the present invention, there is provided a pumping drive means for causing a screw having a spiral shape to reciprocate to form a virtual piston that performs a volumetric pumping operation, thereby enabling the virtual piston to be rotated by the rotation of the screw, The suction force and the discharge pressure are increased.

In addition, since the suction force is raised, the self-absorption of the particle material is facilitated, and the pumping action of the volumetric pumping action is performed along with the transfer by the rotation, so that the transfer object having the same length, such as the transported object or the algae, .

In addition, since the conveying of the conveying object is carried to a long distance by the rotational force of the screw and the virtual piston, the length of the screw does not need to be made longer by the distance of the conveying target point of the conveying object, Production cost will be reduced.

That is, in the conventional pump, when the conveying object is conveyed for 10 m, the conveying object can be conveyed to the conveying target point only by forming the screw to 10 m. However, even if the conveying object is formed with the length of about 1/10, .

Further, since the pump housing, the screw and the driving part are vertically arranged and the driving part is provided at the lowermost part, the bottom surface of the installation object is minimized and maintenance is easy.

BRIEF DESCRIPTION OF DRAWINGS FIG. 1A is a perspective exploded view of a main component according to an embodiment of the present invention; FIG.
FIG. 1B is a perspective exploded view of a main structure of a screw according to an embodiment of the present invention. FIG.
FIG. 2 is a perspective view of an embodiment according to the present invention. FIG.
3 is a cross-sectional side view of an embodiment according to the present invention.
Fig. 4 is an exemplary view showing that a telescopic shaft according to the present invention is implemented with a ball spline shaft as a female part; Fig.
FIG. 5 is an exemplary view showing a telescopic shaft according to an embodiment of the present invention when the spline shaft is used as a female part; FIG.
FIG. 6 is an exemplary view showing that a telescopic shaft according to the present invention is implemented with a serration axis as a female part;
FIG. 7 is an exemplary view showing that a telescopic shaft according to the present invention is implemented with a groin shaft as a shaft; FIG.
FIG. 8 is an exemplary view showing that a telescopic shaft according to the present invention is implemented with a female portion of a bellows shaft; FIG.
9A and 9B are views showing an example in which the pumping driver according to the present invention is constituted by a cam actuator composed of a reciprocating drive column.
10 is an exemplary view showing that the pumping driver according to the present invention is constituted by a cam actuator having cam protrusions and cam grooves.
11 is a view showing an example in which the pumping driver according to the present invention is constituted by a solenoid actuator.
FIG. 12 is an exemplary view showing a pumping actuator according to the present invention constructed as a pneumatic actuator. FIG.
13 is a view showing an example in which the pumping driver according to the present invention is formed of a reciprocating drive pinion gear.
FIG. 14 is an exemplary view showing a check valve provided on a blade of a screw in the practice of the present invention; FIG.
Fig. 15 is an exemplary view showing that a blade of a screw is provided with a check blade in the practice of the present invention. Fig.
Fig. 16 is an exemplary view showing that the screw of the screw is provided with an interference prevention net in the practice of the present invention. Fig.

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

The present invention relates to a method and apparatus for transferring a conveyed object by a screw formed by a spiral wing with rotation and volumetric pumping by a virtual piston, thereby improving the self-attraction force and the discharge pressure, Thereby enabling efficient discharge, minimizing the length of the pump, minimizing damage to the bottom surface of the screw pump installation, and facilitating maintenance.

1 to 3, the present invention includes a screw 200 having a wing 210 spirally formed on the outer periphery of a pump shaft 220, a screw 200 accommodated in the screw 200, A pump housing 100 having a cylindrical inlet port 111 and a discharge port 112 formed on the other side thereof and a screw 200 provided on one side of the pump housing 100 to be fastened with the screw 200, The screw pump 200 and the driving unit 300 are vertically arranged and the driving unit 300 is disposed at the lowermost position and the screw 200 and the driving unit 300 are vertically arranged. 200) so as to form a virtual piston for performing a volumetric pumping operation.

The pump housing 100 is formed in a cylindrical shape and a pumping stroke space of the screw 200 is formed therein. A discharge port 112 is formed at an upper end of the pump housing 100, And an inlet 111 is formed at the lower side surface so as to allow the object to be conveyed on the bottom surface of the object to be installed to flow to the side.

The inlet port 111 of the pump housing 100 according to the present invention may be provided with a suction inducing hopper 111a which is capable of driving a conveying object on the bottom surface of the installation object to the inlet port 111 will be.

The suction induction hopper 111a can be formed by forming a tuck between the suction inducing hopper 111a and the bottom surface of the installation object.

The suction induction hopper 111a is formed so that the bottom surface and the outer surface of the object to be installed are flush with each other and the inlet 111 of the pump housing 110 is located below the bottom surface of the object to be installed.

The suction induction hopper 111a is fixed to the bottom surface of the object to be installed and the lower end of the pump housing 100 is hung on a coupling hole formed at the center of the suction inducing hopper 111a.

Meanwhile, as shown in FIG. 1B, the blades of the screw 200 can be multi-bladed.

The driving unit 300 may selectively implement any one of an electric motor, a hydraulic motor, and an engine.

The pumping driving means includes a pivoting shaft for axially coupling the driving part 300 and the screw 200 so as to absorb a change in axial length, and a pumping driving part for pivotally moving the screw part 200 in the axial direction Respectively.

Hereinafter, a description will be made of an embodiment of the extensible shaft joint portion as follows.

As shown in FIG. 4, the extensible shafts are provided on either one of the driving unit 300 and the screw 200, and the spline grooves are formed on the inner surface of the spline tube, the driving unit 300, and the screw 200 And a spline shaft which is formed on an outer surface of the spline groove and which is axially coupled to the spline tube, and a spline groove accommodated in the spline groove and provided in the spline groove, As shown in FIG.

As shown in FIG. 5, the extensible shafts are provided on either one of the driving unit 300 and the screw 200, and the spline tube and the driving unit 300, which are formed on the inner surface of the spline, And a spline shaft having a spline shaft formed on an outer surface thereof and axially coupled to the spline tube.

As shown in FIG. 6, the extensible shaft is provided on either one of the driving unit 300 and the screw 200, and the serration is formed on the inner surface of the serration tube, the driving unit 300, And a serration shaft provided on one side and formed of serration rods formed on the outer surface and axially coupled to the serration tube.

7, the extensible shafts are formed on one side of the driving unit 300 and the screw 200, and a polygonal tube formed of a polygonal tube, and the other of the driving unit 300 and the screw 200 And a polygonal prism 430 formed of a polygonal bar corresponding to the polygonal tube and formed of a polygonal bar that is axially coupled to the polygonal tube.

As shown in FIG. 8, the extensible shafts and concave portions are constituted by a bellows shaft 440 constituted by a bellows tube which is axially coupled to a drive shaft of the drive unit 300 and a pump shaft of the screw 200 and elongates and contracts in the longitudinal direction .

In addition, the extensible shafts and concave portions can be implemented by applying all the extensible shafts applied to the shaft coupling in addition to the above-described embodiments.

Hereinafter, an embodiment of the pumping driver will be described.

The pumping drive unit includes a cam actuator for pumping the pump shaft 220 of the screw 200 in the axial direction.

9A, the cam actuator includes a reciprocating driving column 511 inclined to the pump shaft 220 and a reciprocating driving column 511 connecting the reciprocating driving column 511 to the shaft housing 310, And a pull bar 512.

The reciprocating driving draw bar 512 is coupled to the shaft housing 310 in a rotatable manner and extensively connected to the end of the draw link 512a and a draw link 512a coupled to the shaft housing 310 in the axial direction, And a column restraining bearing portion 512b for restraining rotation of the outer periphery of the column restraining bearing portion 512b.

9B, the cam actuator has a decelerating shaft 514 that is electrically coupled to the driving unit 300 and the decelerating gear 513. The reciprocating driving column 511, which is inclined to the decelerating shaft 514, And a reciprocating drive draw bar 512 which rotatably restrains the pump shaft 220 by rolling the reciprocating drive column 511.

10, the cam actuator includes a cam protrusion 521 at one side of a pump shaft 220 and an inner wall of the shaft housing 310, and a screw 200 is provided at the other side corresponding to the cam protrusion 521, And a cam groove 522 that reciprocates according to the rotation of the shaft 220.

11, the solenoid actuator 530 includes a solenoid actuator 530 for pumping the screw 200 by magnetic force in the axial direction and returning the screw 200 by the rotational discharge pressure as shown in FIG. will be.

As shown in FIG. 12, the pumping actuator may include a pneumatic actuator 540 for pumping the pump shaft 220 in the axial direction by a pneumatic pressure.

As shown in FIG. 13, the pumping driving unit includes a gear housing 551 that is axially slidably received in the shaft housing 310 and a sliding portion 551 that is slidably mounted on the driving unit 300 side of the gear housing 551. [ A drive bevel gear 552 which is axially supported and axially connected to the drive unit 300; a pump bevel gear 553 which is axially mounted on the pump side of the gear housing 551 and is fixed to the pump shaft 220; A reciprocating driving pinion gear 554 and a reciprocating driving pinion gear 555 provided on both sides so as to be coupled with each other between the pump bevel gear 553 and the pump bevel gear 553 and the reciprocating driving pinion gear 555 provided on the reciprocating driving pinion gear 554, And a reciprocating motion guide groove 556 for guiding the axial housing to reciprocate in the axial direction by limiting the axial flow and allowing the axial flow to flow only in the width direction.

In addition to the above-described embodiments, the present invention can also be implemented by applying a pumping driving method in which the screw 200 is operated in a volumetric pumping operation in conjunction with a rotating operation.

In the virtual piston-type pumping operation of the screw 200 by the pumping drive unit, the return stroke speed is lower than the pressure stroke speed so that the negative pressure in the discharge port 112 is minimized during the return stroke of the screw 200 It is preferable to perform the operation.

Hereinafter, another embodiment of the screw in the practice of the present invention will be described.

It is possible to provide the unidirectional opening means for reducing the negative pressure on the side of the discharge port 112 during the return operation of the screw 200 to the blade 210 of the screw 200 to improve the pumping efficiency.

Here, the unidirectional opening means can be implemented by a check valve 211 provided in the vane 210 as shown in FIG.

Another embodiment of the unidirectional opening unit may include a check blade 212 in which a part of the blade 210 is opened and unfolded toward the discharge port 112 as shown in FIG.

As shown in FIG. 16, the wing 210 having the unidirectional opening means may be provided with an interference prevention network 213 to prevent foreign matter from being caught in the negative pressure decompression process.

In addition, the unidirectional opening means can be implemented in such a manner that the screw 200 is rotated in one direction so that the wing 210 is horizontal in the axial direction during the return stroke.

Hereinafter, the operation of the present invention will be described.

As described above, in the screw pump, the pump housing 100, the screw 200, and the driving unit 300 are vertically arranged and the driving unit 300 is provided at the lowermost position, and the screw 200 is reciprocated And a pivoting driving means for pivotally connecting the driving shaft of the driving unit 300 and the screw 200 so as to absorb a change in axial length, When a vertical screw pump to which the present invention is applied and which is constituted by a pumping driving part for pivotally moving the screw part 200 in the axial direction is intended to be installed on an installation object such as a deck of a ship, The pump coupling hole is drilled to a diameter that can be laterally inserted into the pump coupling hole.

The vertical screw pump according to the present invention is coupled to the pump coupling hole and installed vertically.

As described above, when the vertical screw pump according to the present invention is installed on the deck of the ship and the driving unit 300 is operated, the conveying object on the deck of the ship is opened at the lower portion of the pump housing 100, (111), and is pushed by the screw (200) by the rotation of the driving part (300).

At this time, the screw (200) performs a volumetric pumping operation inside the pump housing (100) by the pumping driving unit of the pumping driving means.

When the volumetric pumping operation is performed by the screw 200 as described above, the cross sectional area projected in the axial direction of the screw 200 is formed in the pumping stroke process by the pumping driving unit, And the discharged object is pumped and discharged toward the discharge port 112 formed to be opened to the upper portion of the pumping housing 100.

Then, the screw 200 is returned to the return stroke by the pumping driving unit, and the conveying object pushed toward the discharge port 112 side through the pumping stroke process is continuously conveyed toward the discharge port 112 by the inertial flow, (200) is to be returned.

As the above process is repeatedly performed, the self-priming force and the discharge pressure are improved, so that the transported object is transported clearly and efficiently, and the pumping work by the self-assist is facilitated by the improvement of the suction force. The object to be transported is clearly transported even if it is not formed as long as the distance.

If the return stroke of the pumping actuation unit is lower than the pumping stroke, the transfer resistance of the object to be inertially flowed is minimized, and a negative pressure is not formed on the discharge port 112 side in the pumping return stroke of the screw 200 will be.

In the embodiment of the present invention, as shown in FIG. 3A, a suction induction hopper 111a, which forms a step between the inlet 111 of the pump housing 100 and the bottom surface of the object to be installed, By moving the conveying object on the bottom surface of the installation object to the suction induction hopper 111a, the inlet port 111 is filled with the conveying object even when the conveying object is small, and the conveyance of the conveying object is clear and easy .

3B, when the inlet 111 of the pump housing 110 is positioned at a position lower than the bottom surface of the object to be installed, The conveying object positioned on the deck, which is the bottom surface of the object to be installed, flows into the suction induction hopper 111a recessed from the deck and is guided to the inlet 111 of the pump housing 110, Is always locked in the conveying object so that the conveying of the conveying object is made clear and easy.

Meanwhile, as shown in FIG. 3B, the vertical screw pump according to the present invention is removed, and the upper part of the suction induction hopper 111a fixed to the deck of the ship is covered. As a result, So that a work disorder is not caused.

As shown in FIGS. 4 to 7, the expansion and contraction axis may include a ball spline shaft 400 and a spline shaft 410, a serration shaft concave 420, and a polygonal shaft 430 The coupling between the driving unit 300 and the screw 200 is facilitated.

If the bellows shaft 440 is constructed as shown in FIG. 8, the noise is minimized during the virtual piston pumping process by the pumping driving unit.

In addition, if the pumping driver is constructed as a cam actuator as shown in FIG. 9A, the configuration is simplified and the operation is clearly made.

9B, there is provided a reciprocating driving column 511 having a decelerating shaft 514 which is electromagnetically coupled to the driving unit 300 and the decelerating gear 513, and which is inclined on the decelerating shaft 514 And a reciprocating drive draw bar 512 for rotatably restraining the pump shaft 220. The virtual piston operation of the screw 200 is easily adjusted in comparison with the rotational speed of the pump shaft 220 .

11 and 12, when the solenoid actuator 530 and the pneumatic-pressure actuator 540 are used, the virtual piston motion of the screw 200 is clearly performed and the control is easy .

13, the gear housing 551, the drive bevel gear 552, the pump bevel gear 553, and the reciprocating drive unit 553, which are housed in the shaft housing 310 so as to be slidable in the axial direction, The virtual piston operation according to the number of revolutions of the screw 200 can be easily controlled through driving and the gear ratio adjustment of the pump bevel gear and the reciprocating drive pinion gear 554.

14 and 15, when the check valve 211 or the check blade 212 is provided in the blade 210 of the screw 200, The conveying object which is inertially moved through the check valve 211 or the check blade 212 is moved in the return stroke of the screw 200 so that the conveying resistance of the conveying object is minimized and the discharging port 112 are not formed.

16, when the wedge 210 having the unidirectional opening means is provided with the interference prevention network 213 at the inlet port 111 side, the check valve 211 or the check wing 212 may be used as a fluid Only the conveyed object, such as powder and air, which is prevented from being caught, is moved, thereby preventing the check valve 211 or the check blade 212 from operating due to the foreign matter.

If the unidirectional opening means is configured such that the screw 200 is rotated in one direction so that the wing 210 is horizontally aligned in the axial direction during the return stroke, the screw 200 is rotated by the wing 210 during the return stroke, The flow resistance of the conveyed object that is inertially flowed is minimized, so that no negative pressure is formed on the discharge port 112 side in the pumping return stroke.

In addition, if the screw 200 and the pump housing 100 are formed in a short form, the friction area between the screw 200 and the pumping stroke space is reduced, thereby reducing the resistance of the pump 200 during pumping operation.

As described above, the screw pump according to the present invention simultaneously performs volumetric pumping transfer along with rotation transmission by the screw 200, so that it has a strong suction force and a strong earth output of a high pressure increase.

In addition, the screw pump according to the present invention is capable of transferring a conveyed object without damaging the length of the seaweed having a length such as the seaweed or the sea-stall, and heating without damaging it, because the conveyance of the conveyed object has a continuous conveying path and is made by volumetric pumping action.

In addition, the present invention is capable of weighing marine algae, such as biting, due to a small change in water content in the pumping transfer process of seaweeds, and is capable of transferring without transporting the object to be conveyed by forming a strong suction force.

In addition, the screw pump according to the present invention is capable of immersing the high viscous sludge such as foreign matter such as manure and the mixture of mortar and pulp into a self-sustaining / high-pressure / high-lift conveying system.

In addition, the screw pump according to the present invention is capable of transporting and loading particulate matter such as coal, gravel, leaves, feed, road surface waste, and the like.

In addition, the screw pump according to the present invention is capable of transferring special breath including organisms such as shellfish and fish, and pumping for fertilizer application is possible.

In addition, the present invention can be carried out by applying a large-volume pump, a high-pressure propellant pump, and a large particle pump.

100: pump housing
111: inlet port 111a: suction induction hopper 112:
200: Screw
210: wing 211: check valve 212: check wing 213:
220: Pump shaft
300: driving part 310: shaft housing
400: Ball spline shaft
410: spline shaft joint part 420: serration axis joint part
430: polygonal axis 440: bellows axis
511: reciprocating drive column
512: reciprocating drive tow bar
512a: pull link 512b: column restraining bearing portion
513: Reduction gear 514: Reduction shaft
521: Cam protrusion 522: Cam groove
530: Solenoid actuator
540: Pneumatic and hydraulic actuators
551: Gear housing 552: Drive bevel gear
553: Pump bevel gear 554: reciprocating drive pinion gear
555: reciprocating driving traction protrusion 556: reciprocation induction groove

Claims (6)

A screw 200 in which a wing 210 is spirally formed on an outer circumference of a pump shaft 220 and a screw 200 are accommodated and an inlet 111 is formed on one side and a discharge port 112 is provided on the other side And a drive unit 300 provided at one side of the pump housing 100 to be rotatable with the screw 200 to rotate the screw 200, the screw pump comprising:
A virtual piston in which the pump housing 100, the screw 200 and the driving unit 300 are vertically arranged and the driving unit 300 is provided at the lowermost position and the screw 200 is reciprocated to perform a volumetric pumping operation And pumping driving means for causing the pumping means to be formed;
The pump housing 100 is formed in a cylindrical shape and a pumping stroke space of the screw 200 is formed therein. A discharge port 112 is formed at an upper end of the pump housing 100, An inlet port 111 is formed in the bottom surface of the mounting object so as to allow the article to be transported to the side surface,
The pumping driving unit includes a pivoting driving unit for pivotally moving the screw shaft 200 and the extensible shafts for screwing the screw 200 so as to absorb a change in the axial length of the screw 200 in the axial direction ,
The extension /
A spline groove provided on one side of the driving unit 300 and the screw 200 and provided on the other side of the screw 200 and the driving unit 300 and the spline groove formed on the inner surface, A spline shaft being axially coupled with the pipe, and a spline shaft including a spline pipe and a spline groove accommodated in a spline groove provided in the spline bar;
A spline tube provided on one side of the driving unit 300 and the screw 200 and provided on the other side of the spline tube and the driving unit 300 and the screw 200 formed on the inner surface of the spline, A spline shaft constituted by spline rods which are axially coupled to each other;
A serration tube provided on one side of the driving unit 300 and the screw 200 and provided on the other side of the serration tube and the driving unit 300 and the screw 200 formed on the inner surface, A serration shaft consisting of serration rods axially joined to a serration tube;
A polygonal tube provided on one side of the driving unit 300 and the screw 200 and formed on the other side of the driving unit 300 and the screw 200, (430) formed of a polygonal bar formed by a sieve and axially coupled to a polygonal tube;
And a bellows shaft 440 constituted by a bellows tube body in which a driving shaft of the driving unit 300 and a pump shaft of the screw 200 are axially coupled and elongated and contracted in a longitudinal direction;
Wherein the vertical screw pump is a pumping type vertical screw pump.

The method of claim 1, further comprising:
In the volumetric pumping operation of the screw 200 by the pumping driving unit, the return stroke speed is operated to be slower than the pressure stroke speed so that the negative pressure in the discharge port 112 is minimized in the return stroke of the screw 200 Features a pumped vertical screw pump.

The method of claim 1, further comprising:
Wherein the pump driving unit comprises a cam actuator for pumping the pump shaft (220) of the screw (200) in the axial direction. 4. The method of claim 3, further comprising:
The cam actuator
A reciprocating drive column 511 inclined to the pump shaft 220 and a reciprocating drive draw bar 512 for coupling the reciprocating drive column 511 to the shaft housing 310 by rolling, The bar 512 is rotatably and retractably coupled to the end of the tow link 512a and a draw link 512a coupled to the shaft housing 310 in an axially rotationally rotated manner to rotate the outer periphery of the reciprocating drive column 511 And a column restraining bearing portion 512b for restricting the column restraint bearing portion 512b;
A reciprocating drive column 511 inclined to the decelerating shaft 514 and the reciprocating drive column 511 are connected to the decelerating shaft 514 by a rolling clutch 514, And a reciprocating driving draw bar 512 for rotatably restraining the pump shaft 220;
A cam protrusion 521 is provided at one side of the pump shaft 220 and an inner wall of the shaft housing 310 and a cam groove 521 is formed at the other side of the cam protrusion 521 to reciprocate the screw 200 in accordance with the rotation of the pump shaft 220 (522). ≪ Desc / Clms Page number 24 >
The method of claim 1, further comprising:
The pumping driver
And a solenoid actuator 530 for pumping the screw 200 by a magnetic force in the axial direction and causing the screw 200 to return by the rotational discharge pressure;
And a pneumatic / hydraulic actuator (540) for pumping the pump shaft (220) in the axial direction by a pneumatic pressure.
The method of claim 1, further comprising:
The pumping driver
A gear housing 551 which is slidably received in the shaft housing 310 so as to be slidable in an axial direction and a drive bevel gear 552 which is slidably mounted on the drive unit 300 side of the gear housing 551 and is fixed to the drive unit 300 A pump bevel gear 553 which is axially mounted on the pump side of the gear housing 551 and is fixed to the pump shaft 220 and a pump bevel gear 553 which is installed on both sides of the drive bevel gear 552 and the pump bevel gear 553, The reciprocating driving pull projection 555 and the reciprocating driving pull projection 555 provided on the reciprocating driving pinion gear 554 and the reciprocating driving pinion gear 554 restrict the axial flow and flow only in the width direction, And a reciprocating motion induction groove (556) for guiding the housing to reciprocate in the axial direction.

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