Compression apparatus

Information

  • Patent Grant
  • 6688854
  • Patent Number
    6,688,854
  • Date Filed
    Wednesday, November 27, 2002
    22 years ago
  • Date Issued
    Tuesday, February 10, 2004
    20 years ago
Abstract
There is disclosed a high-pressure compressor comprising a compression mechanism for reciprocating/driving a piston with respect to a conventional cylinder by rotation of a motor and compressing an operating fluid sucked by this driving to generate the high-pressure operating fluid according to improvements in a piston shape, positions of a cylinder operation surface and the piston, specifics shapes of the cylinder and piston, and connecting constitution of the piston to a connecting rod, which solves problems such as occurrence of wear on a cylinder inner surface by displacement of the piston, size enlargement by an increase of a removal capacity, difficulty in processing the piston and connecting rod, and a large top clearance.
Description




BACKGROUND OF THE INVENTION




The present invention relates to a high-pressure compressor of a compression type provided with a compression mechanism for compressing a sucked operating fluid to generate a high-pressure operating fluid, particularly to an improvement of a compression mechanism for reciprocating/driving a piston with respect to a cylinder by rotation of a motor.




For a high-pressure compressor of a compression type provided with a compression mechanism for reciprocating/driving a piston with respect to a cylinder by rotation of a motor and compressing an operating fluid sucked by the driving to generate a high-pressure operating fluid, as the invention by the present applicant, a multistage compression apparatus (hereinafter referred to the prior art) is disposed as one high-pressure gas compressor invented before the application date of the present application, for example, in Japanese Patent Application Laid-Open No. 81780/1999.




The prior art will be described hereinafter based on

FIGS. 1

to


4


. A multistage compression apparatus


100


constitutes a four-stage compressor provided with four compression sections (compression stages)


101


,


102


,


103


,


104


. The compression sections


101


and


103


are arranged on a horizontal axis


106


, the compression sections


102


and


104


are arranged on a horizontal axis


105


, and a reciprocating compression mechanism is constituted in which a piston as a movable member reciprocates/operates on these axes


106


,


105


in a cylinder as a fixed member. Thereby, the operating fluid sucked via a suction pipe


118


is compressed in the first compression section


101


, subsequently the operating fluid compressed in the first compression section


101


is passed via a pipeline


5


into the second compression section


102


and compressed, the operating fluid compressed in the second compression section


102


is passed via a pipeline


6


into the third compression section


103


and compressed, the operating fluid compressed in the third compression section


103


is passed via a pipeline


7


into the fourth compression section


104


and compressed, and the high-pressure operating fluid provided with a predetermined pressure and flow rate in this manner is discharged via a discharge pipe


8


.




Examples of the operating fluid in the multistage compression apparatus


100


include nitrogen, natural gas, sulfur hexafluoride (SF6), air, and other so-called gases, and the multistage compression apparatus


100


is applied to a natural gas charging machine to a car bomb using a natural gas, high-pressure nitrogen gas supply to a gas injection molding machine using a high-pressure nitrogen gas during injection molding of synthetic resin, a charging machine of high-pressure air to an air bomb, and the like.




In the multistage compression apparatus


100


, a piston


51


in the first compression section


101


and a piston


53


of the third compression section


103


are connected to a yoke


1


A on the axis


106


, and a cross slider


2


A movably disposed to cross the axis


106


in the yoke


1


A is connected to a crank shaft


4


via a crank pin


3


. The axis


105


forms an angle of 90 degrees with the axis


106


in a vertical view. Moreover, a piston


52


of the second compression section


102


and a piston


54


of the fourth compression section


104


are connected to a yoke


1


B on the axis


105


, and a cross slider


2


B movably disposed to cross the axis


105


in the yoke


1


B is connected to the crank shaft


4


via the crank pin


3


.




The crank shaft


4


is rotated by an electric motor (not shown) disposed below the compression sections


101


to


104


, the crank pin


3


disposed on the crank shaft


4


in an eccentric manner is rotated around the crank shaft


4


, with respect to the yoke


1


A the cross slider


2


A moves to handle displacement of the crank pin


3


in a direction of axis


105


, the yoke


1


A moves to handle the displacement of a direction of axis


106


, and the pistons


51


,


53


reciprocate only in the direction of the axis


106


.




On the other hand, with respect to the yoke


1


B, the cross slider


2


B moves to handle the displacement of the crank pin


3


in the direction of axis


106


, the yoke


1


B moves to handle the displacement of the direction of axis


105


, and the pistons


52


,


54


then reciprocate only in the direction of the axis


105


.





FIG. 4

is a sectional view showing a structure of the first compression section


101


of the multistage compression apparatus


100


. The first compression section


101


is provided with a first compression chamber


58


and a second compression chamber


59


before and after the piston


51


. When the piston


51


advances and valves a, b are closed, the operating fluid is sucked into the first compression chamber


58


via opened valves e, f from directions shown by arrows. Additionally, when the operating fluid of the second compression chamber


59


is compressed to reach a predetermined pressure, the fluid is discharged to the outside via opened valves c, d, and fed to the next second compression section


102


via the pipeline


5


as shown by an arrow.




Subsequently, when the piston


51


moves backward, the valves e, f are closed, the operating fluid in the first compression chamber


58


is compressed to reach the predetermined pressure and open the valves a, b, and the operating fluid is discharged to the second compression chamber


59


. Numeral


60


denotes a rod guide for smoothly guiding a connecting rod


57


to a predetermined position so that no vibration occurs.




As described above, the first compression section


101


of the multistage compression apparatus


100


is a double compression mechanism (double action mechanism) structured to suck, compress and discharge the operating fluid in two stages in one cylinder


55


. The second, third and fourth compression sections


102


,


103


,


104


do not comprise the double compression mechanism like the first compression section


101


, and comprise a so-called single action mechanism constituted to perform a usual operation of compressing the gas sucked into the cylinder in one stage in the reciprocating motion of the piston with respect to the cylinder.




In the aforementioned constitution, a nitrogen gas as the operating fluid sucked via the suction pipe


118


indicates a pressure of about 0.05 MPa (G), and is compressed by the first compression section


101


until the pressure indicates about 0.5 MPa (G), and the compressed nitrogen gas is supplied to the second compression section


102


via the pipeline


5


. The nitrogen gas is compressed to indicate about 2 MPa (G) in the second compression section


102


, and the compressed nitrogen gas is supplied to the third compression section


103


via the pipeline


6


. The nitrogen gas is compressed to indicate about 7 to 10 MPa (G) in the third compression section


103


, and the compressed nitrogen gas is supplied to the fourth compression section


104


through the pipeline


7


. In the fourth compression section


104


, the high-pressure gas (high-pressure operating fluid) compressed to indicate about 20 to 30 MPa (G) is supplied to an accumulator via the discharge pipe


8


, and the high-pressure nitrogen gas is supplied to a gas injection molding machine from the accumulator.




In the aforementioned prior art, as a first constitution, for the pistons


53


,


54


of the third and fourth compression sections


103


and


104


, as shown in FIG.


5


and

FIG. 6

as an enlarged view of a circle P of

FIG. 5

, a plurality of labyrinth grooves


70


are formed in the peripheral surfaces of the pistons


53


,


54


, in the compression mechanism, a gap of 2 to 6 μm (micrometers) is formed between the piston


53


,


54


and a liner cylinder


73


A,


74


A disposed on the inner surface of the cylinder


73


,


74


, and the gas flowing through the gap flows into the labyrinth groove


70


and generates a turbulence for a gas sealing system to form a so-called non-lubricating labyrinth seal structure. Moreover, a tip end peripheral edge


75


of the piston


53


,


54


is obliquely and linearly chamfered, so-called C-chamfered, and an open edge


76


of the labyrinth groove


70


is formed as a sharp edge.




Moreover, as a second constitution, as shown in

FIG. 7

, in the third and fourth compression sections


103


,


104


, in a top dead point in reciprocating/driving of the piston


53


,


54


, a rear end


78


of the piston


53


,


54


is positioned inside the liner cylinder


73


A,


74


A by a length L


1


. Moreover, as shown in

FIG. 8

, in a lower dead point, a tip end


77


of the piston


53


,


54


is positioned inside the liner cylinder


73


A,


74


A by a length L


2


. Specifically, the length L


1


, L


2


indicates a friction distance when the piston


53


,


54


is displaced with respect to the liner cylinder


73


A,


74


A.




Furthermore, as a third constitution, as shown in

FIG. 9

, in the second compression section


102


, an aluminum cylinder


72


forms a uniform cylindrical inner surface


81


with the same inner diameter (diameter of 75 mm) toward a discharge plate


80


, and the piston


52


reciprocates along the cylindrical inner surface


81


. The piston


52


is provided with a plurality of PTFE piston rings


83


at intervals to seal with the cylinder


72


. As shown in

FIG. 10

, a piston plate


84


is fixed to the tip end of the piston


52


to support the piston ring


83


on the tip end.




Additionally, as a fourth constitution, as shown in

FIG. 11

, in the third and fourth compression sections


103


and


104


, the pistons


53


,


54


are connected to the yokes


1


A,


1


B via connecting rods


85


,


86


, respectively, and reciprocate in the cylinders


73


,


74


by rotation of the electric motor. In the connection of the piston


53


to the connecting rod


85


, and the connection of the piston


54


to the connecting rod


86


, male connectors


87


,


88


extended from the pistons


53


,


54


engage with female connectors


89


,


90


formed in the connecting rods


85


,


86


so that mutual rotation is possible. Numerals


91


,


92


denote guide rings disposed on the connecting rods


85


,


86


, respectively. Numerals


79


,


79


A denote reinforcing materials embedded in the connecting rods


85


,


86


in positions where the male connectors


87


,


88


contact.




Moreover, as a fifth constitution, in the third and fourth compression sections


103


and


104


, the pistons


53


,


54


shown in

FIG. 12

have flat surfaces on tip ends as shown in

FIGS. 5 and 6

. Furthermore, the respective tip end peripheral portions


75


are obliquely and linearly chamfered, so-called C-chamfered.




In the aforementioned prior art, in the first constitution shown in

FIGS. 5 and 6

, there is a problem that the inner surfaces of the cylinders


73


,


74


are worn by the pistons


53


,


54


. Specifically, the piston


53


,


54


is disposed in the horizontal direction, and is displaced downward by its weight by the gap between the piston


53


,


54


and the liner cylinder


73


A,


74


A to contact the inner surface of the liner cylinder


73


A,


74


A before the compressor starts. When the compressor starts in this state, a phenomenon disadvantageously occurs in which the inner surface of the liner cylinder


73


A,


74


A is scraped by the tip end of the piston


53


,


54


and the edge of the opening end of the labyrinth groove


70


.




Moreover, in the aforementioned prior art, in the second constitution shown in

FIGS. 7 and 8

, there is a problem that the inner surfaces of the liner cylinders


73


A,


74


A are worn by the pistons


53


,


54


. Specifically, in the top and lower dead points of the pistons


53


,


54


, the ends


77


,


78


of the pistons


53


,


54


are positioned in the liner cylinders


73


A,


74


A by the lengths L


1


, L


2


. Therefore, in the downward displacement of the pistons


53


,


54


, the phenomenon occurs in which the tip and rear ends of the pistons


53


,


54


scrape the inner surfaces of the liner cylinders


73


A,


74


A.




Furthermore, in the prior art, in the third constitution shown in

FIGS. 9 and 10

, since the inner surface of the cylinder


72


is a uniform cylindrical inner surface with the same inner diameter, in order to enlarge a removal capacity in a compression process, a cylinder inner diameter and a piston outer diameter have to be enlarged, and there is a problem that size enlargement necessarily results.




Additionally, in the prior art, in the fourth constitution shown in

FIG. 11

, the piston is connected to the connecting rod by the engaging connection of the male connector with the female connector, and there is a problem that a processing for accurately keeping a processing precision of the engaging connection portion is considerably laborious. Moreover, the reinforcing material is necessary for maintaining performance.




Moreover, in the fifth constitution in the prior art, there is a problem that the inner surfaces of the liner cylinders


73


A,


74


A are worn by the pistons


53


,


54


. Specifically, since the piston


53


(


54


) in

FIG. 12

has the flat surface as the tip end surface, and the tip end peripheral edge


75


is C-chamfered, in the downward displacement of the pistons


53


,


54


the phenomenon of scraping the inner surfaces of the liner cylinders


73


A,


74


A occurs, and there is also a problem that a top clearance increases.




SUMMARY OF THE INVENTION




In consideration of the aforementioned problems, an object of the present invention is to provide a compression apparatus of a compression system high-pressure compressor in which wear of a cylinder inner surface as in the prior art is prevented, removal capacity is increased, processing is facilitated, and top clearance is reduced so that properties can be enhanced. For this purpose, as one concrete means for solving the problem, there is provided a high-pressure compressor comprising a compression mechanism for reciprocating/driving a piston with respect to a cylinder by rotation of a motor and compressing an operating fluid sucked by the driving to generate a high-pressure operating fluid. In the high-pressure compressor, the compression mechanism comprises a labyrinth seal structure in which a plurality of labyrinth grooves are formed in a peripheral surface of the piston and no lubrication is performed between the peripheral surface of the piston and an operation inner surface of the cylinder, and a tip end peripheral edge of the piston and an opening end of the labyrinth groove are R-chamfered.




Moreover, according to the present invention, as one concrete means for solving the problem, there is provided a high-pressure compressor comprising a compression mechanism for reciprocating/driving a piston with respect to a cylinder by rotation of a motor and compressing an operating fluid sucked by the driving to generate a high-pressure operating fluid. In the high-pressure compressor, the compression mechanism comprises a labyrinth seal structure in which a plurality of labyrinth grooves are formed in a peripheral surface of the piston and no lubrication is performed between the peripheral surface of the piston and an operation inner surface of the cylinder, and for a relation between the piston and the cylinder, in a top dead point and a lower dead point in the reciprocating/driving of the piston, a tip end peripheral edge and a rear end peripheral edge of the piston are substantially positioned not to enter the operation inner surface of the cylinder.




Furthermore, according to the present invention, as one concrete means for solving the problem, there is provided a high-pressure compressor comprising a compression mechanism for reciprocating/driving a piston with respect to a cylinder by rotation of a motor and compressing an operating fluid sucked by the driving to generate a high-pressure operating fluid. In the high-pressure compressor, the compression mechanism comprises a non-lubricating seal structure between an operation inner surface of the cylinder and the piston, a tip end small diameter portion is formed on the piston, and a small diameter compression section into which the tip end small diameter portion of the piston is inserted when the piston is in a top dead point, and a large diameter portion for forming a compression space in the periphery of the tip end small diameter portion of the piston when the piston is in a lower dead point are continuously formed on the cylinder.




Additionally, according to the present invention, as one concrete means for solving the problem, there is provided a high-pressure compressor comprising a compression mechanism for reciprocating/driving a piston with respect to a cylinder by rotation of a motor and compressing an operating fluid sucked by the driving to generate a high-pressure operating fluid. In the high-pressure compressor, the compression mechanism comprises a non-lubricating seal structure between an operation inner surface of the cylinder and the piston, and the piston is connected to a connecting rod by pressing a connecting flange portion extended to a rear end of the piston in a connection space formed in the connecting rod by a spring so that the piston can oscillate with respect to the connecting rod.




Moreover, according to the present invention, as one concrete means for solving the problem, there is provided a high-pressure compressor comprising a compression mechanism for reciprocating/driving a piston with respect to a cylinder by rotation of a motor and compressing an operating fluid sucked by the driving to generate a high-pressure operating fluid. In the high-pressure compressor, the compression mechanism comprises a non-lubricating seal structure between an operation inner surface of the cylinder and the piston, and a shape of a tip end of the piston and a shape of an inner surface of a cylinder head opposite to the tip end are formed in substantially the same R shape.




Furthermore, according to the present invention, there is provided a compression apparatus, provided with a plurality of stages of compression sections each comprising a cylinder and a piston, for successively passing a gas through the respective compression sections to compress and supply the gas, in which the compression section of the final stage and the compression section of the stage before the final stage are provided with plunger pistons.




Additionally, in the aforementioned invention, a gap in a diametric direction between the cylinder of the compression section of the final stage and the piston reciprocating/operating inside the cylinder is smaller than a gap between the cylinder of the stage before the final stage and the piston reciprocating/operating in the cylinder.




Moreover, in the aforementioned invention, the gap of the diametric direction between the cylinder of the compression section of the stage before the final stage and the piston reciprocating/operating in the cylinder is in a range of 3 to 10 μm.




Furthermore, in the aforementioned invention, the gap of the diametric direction between the cylinder of the compression section of the final stage and the piston reciprocating/operating in the cylinder is in a range of 2 to 8 μm.




Additionally, in the aforementioned invention, the piston reciprocating/operating in the cylinder of the compression section of the stage before the final stage is provided with a plurality of grooves on a surface, and a ratio (B/A) of a groove depth B to a groove width A is in a range of 0.2 to 0.5.




Moreover, in the aforementioned invention, the compression section is constituted of four stages.




Furthermore, according to the present invention, there is provided a compression apparatus comprising a plurality of compression sections. At least one of the compression sections comprises a plunger piston type compressor, the plurality of compression sections are connected in series by a connection pipe, and a compression process of feeding an operating fluid compressed by the compression section of a previous stage to the compression section of a subsequent stage, and compressing the operating fluid in the compression section of the subsequent stage is successively performed to generate the high-pressure operating fluid. In the compression apparatus, a plunger piston in the plunger piston type compressor is sealed by a labyrinth seal constituted by a plurality of labyrinth grooves, the labyrinth grooves are formed so that a forming density decreases to the side of a back pressure chamber from the side of a compression chamber, and a seal property is improved.




Additionally, there is provided a compression apparatus comprising: compression means provided with a plurality of compression sections; driving means for driving the compression means; and a sealed case in which the driving means is disposed and whose top portion closely abuts on the compression means. In the compression apparatus, a relief valve, opened when a pressure in the sealed case is equal to or more than a predetermined pressure, is disposed on a bottom of the sealed case, and worn powder of a movable portion, and the like can be discharged to the outside of the apparatus via the relief valve without disassembling/cleaning the apparatus.




Moreover, according to the present invention, there is provided a compression apparatus in which at least one reciprocating compression section of a plurality of reciprocating compression sections is constituted by a plunger pump, and the plurality of reciprocating compression sections are connected to compress a required gas in multiple stages. In the compression apparatus, the plunger pump comprises a piston inserted into a ceramic cylinder liner, and a connecting rod connected to the piston, a sleeve is interposed as a pressure resistant structure member between the cylinder liner and a plunger pump main body, and the cylinder liner and sleeve are fixed to the plunger pump main body via a fixing bolt.




Furthermore, in the aforementioned invention, elastic cushion members such as a leaf spring are interposed and attached between a connecting rod sleeve into which the connecting rod is inserted and the fixing bolt.




Additionally, in the aforementioned invention, one or two or more pressure release grooves are disposed through a thickness direction in a surface by which the sleeve as the pressure resistant structure member contacts the fixing bolt.




Moreover, in the aforementioned invention, one or two or more pressure release holes are disposed through the connecting rod sleeve.




Furthermore, in the aforementioned invention, a width of either one or both of a piston ring groove and a guide ring groove, disposed in the piston, for attaching a piston ring and a guide ring, is larger than the width of the ring itself.




Additionally, according to the present invention, there is provided a compression apparatus, provided with at least one pair of opposite pistons, a yoke to which the pistons are fixed, and a cross slider for sliding and moving in the yoke, for obtaining a reciprocating motion of the piston from a rotation motion of a crank shaft through conversion by a scotch yoke mechanism, in which a cover provided with an opening in a middle portion not to inhibit a crank pin motion is fixed and disposed to sandwich the yoke.




Moreover, in the aforementioned invention, the cover is shrink-fitted and fixed to the yoke.




Furthermore, according to the present invention, in the aforementioned compression apparatus, a position of at least one pair of opposite positions is provided with no piston, and the position is provided with a connecting rod fixed to the yoke, and a cylinder for guiding the connecting rod so that the connecting rod can reciprocate.




Additionally, according to the present invention, there is provided a compression apparatus, provided with a plurality of reciprocating compression sections, for compressing a gas in multiple stages, in which at least the reciprocating compression section of the first stage is provided with a first compression chamber and a second compression chamber, and a double compression structure of discharging a gas sucked and compressed in the first compression chamber to the second compression chamber and again compressing the gas and subsequently discharging and feeding the gas to the reciprocating compression section of the next stage is disposed.











BRIEF DESCRIPTION OF THE DRAWINGS





FIG. 1

is a plan view of a multistage compression apparatus of one embodiment as an object of the present invention.





FIG. 2

is a plan view showing a section of each compression mechanism of the multistage compression apparatus of one embodiment as the object of the present invention.





FIG. 3

is a plan view of a yoke and cross slider of the multistage compression apparatus according to one embodiment as the object of the present invention.





FIG. 4

is a sectional view of the compression mechanism of a first stage of the multistage compression apparatus according to one embodiment as the object of the present invention.





FIG. 5

is a side view of a piston according to a prior-art first constitution.





FIG. 6

is an enlarged view of a circle P of FIG.


5


.





FIG. 7

is a diagram showing a relation between a piston top dead point and a liner cylinder according to a prior-art second constitution.





FIG. 8

is a diagram showing a relation between a piston lower dead point and the liner cylinder according to the prior-art second constitution.





FIG. 9

is a diagram showing a relation between a piston and a cylinder according to a prior-art third constitution.





FIG. 10

is a schematic view of the piston according to the prior-art third constitution.





FIG. 11

is a schematic view of the piston of a connecting rod system according to a prior-art fourth constitution.





FIG. 12

is a schematic view of a compression section according to a prior-art fifth constitution.





FIG. 13

is a side view of the piston of the present invention with respect to the prior-art first constitution.





FIG. 14

is an enlarged view of a circle S of FIG.


13


.





FIG. 15

is a diagram showing the relation between the piston top dead point and the liner cylinder of the present invention with respect to the prior-art second constitution.





FIG. 16

is a diagram showing the relation between the piston lower dead point and the liner cylinder of the present invention with respect to the prior-art second constitution.





FIG. 17

is a schematic view of one embodiment of the piston of the present invention with respect to the prior-art third constitution.





FIG. 18

is a diagram showing the relation between the piston lower dead point and the liner cylinder of the present invention with respect to the prior-art third constitution.





FIG. 19

is a diagram showing the relation between the piston top dead point and the liner cylinder of the present invention with respect to the prior-art third constitution.





FIG. 20

is a schematic view of the piston of the connecting rod system of the present invention with respect to the prior-art fourth constitution.





FIG. 21

is a schematic view of the piston of the connecting rod system according to another embodiment of the present invention with respect to the prior-art fourth constitution.





FIG. 22

is a schematic view of the compression section of the present invention with respect to the prior-art fifth constitution.





FIG. 23

is an explanatory view showing a main part of still another embodiment.





FIG. 24

is an explanatory view showing a part of

FIG. 23

in an enlarged manner.





FIG. 25

is an explanatory view showing the structure of a four-stage compression apparatus.





FIG. 26

is an explanatory view showing a driving mechanism of the four-stage compression apparatus shown in FIG.


25


.





FIG. 27

is a partially broken side view of the multistage compression apparatus showing still another embodiment.





FIG. 28

is a horizontal sectional view of compression means.





FIG. 29

is a side view of a fourth piston.





FIG. 30

is a diagram showing leak properties when labyrinth grooves are formed at equal pitches and irregular pitches.





FIG. 31

is a partially broken side view of the multistage compression apparatus showing a conventional art.





FIG. 32

is a top plan view of FIG.


31


.





FIG. 33

is a side view of the fourth piston.





FIG. 34

is an explanatory view showing a section of still another embodiment of the multistage compression apparatus of the present invention.





FIG. 35

is an explanatory view showing a section of the embodiment of a fourth reciprocating compression section of the multistage compression apparatus of the present invention shown in FIG.


34


.





FIG. 36

is an explanatory view showing a section of the embodiment of a third reciprocating compression-section of the multistage compression apparatus of the present invention shown in FIG.


34


.





FIG. 37

is an explanatory view showing a section of another embodiment of the fourth reciprocating compression section of the multistage compression apparatus of the present invention shown in FIG.


34


.





FIG. 38

is an explanatory view showing a section of another embodiment of the fourth reciprocating compression section of the multistage compression apparatus of the present invention shown in FIG.


34


.





FIG. 39A

is an explanatory view showing a longitudinal section of a sleeve as a pressure resistant structure member shown in

FIG. 38

, and

FIG. 39B

is a bottom plan view of the sleeve as the pressure resistant structure member shown in FIG.


38


.





FIG. 40

is an explanatory view showing a section of the piston provided with a piston ring and guide ring for use in the present invention.





FIG. 41

is an explanatory view showing a section of the piston provided with a conventional piston ring and guide ring.





FIG. 42

is an explanatory view showing a section of a conventional multistage compression apparatus.





FIG. 43

is an explanatory view showing a section of another embodiment.





FIG. 44

is an explanatory view showing the yoke, cross slider, and the like of the multistage compression apparatus of the present invention shown in FIG.


43


.





FIG. 45

is an explanatory view showing a partial section of the yoke, cross slider, and the like of the multistage compression apparatus of the present invention shown in FIG.


43


.





FIG. 46

is a side view of the yoke shown in FIG.


45


.





FIG. 47

is an explanatory view showing a main part of another multistage compression apparatus of the present invention.





FIG. 48

is an explanatory view showing a main part of the multistage compression apparatus according to further embodiment of the present invention.





FIG. 49

is an explanatory view showing a sectional structure of a first reciprocating compression section of the multistage compression apparatus of the present invention shown in FIG.


48


.





FIG. 50

is an explanatory view showing a sectional structure of the first reciprocating compression section of a conventional multistage compression apparatus.





FIG. 51

is an explanatory view showing the section of the conventional multistage compression apparatus.











DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT




Embodiments of the present invention will next be described. In the present invention, since a specific part of the compression type high-pressure compressor


100


described in the aforementioned prior art is developed as the invention, components equivalent to those of the high-pressure compressor


100


described in the aforementioned prior art are denoted by the reference numerals of the high-pressure compressor


100


described in the aforementioned prior art.




The present invention with respect to the first constitution in the aforementioned prior art is shown in FIG.


13


and

FIG. 14

as an enlarged view of a circle S of FIG.


13


. Specifically, in the high-pressure compressor


100


provided with a compression mechanism for reciprocating/driving a piston


53


(


54


) with respect to a cylinder


73


(


74


) by rotation of a motor and compressing an operating fluid sucked by the driving to generate a high-pressure operating fluid, the compression mechanism is provided with a labyrinth seal structure in which a plurality of labyrinth grooves


70


are formed in a peripheral surface of the piston


53


(


54


), and no lubrication is performed between the piston and an operation inner surface of the cylinder


73


(


74


), that is, a liner cylinder


73


A,


74


A, and a tip end peripheral edge


75


of the piston


53


(


54


) and an opening end


76


of the labyrinth groove


70


are R-chamfered. The multistage compression apparatus of the high-pressure compressor


100


is shown. As an appropriate embodiment of the R chamfer, the tip end peripheral edge


75


indicates 1R, the opening end


76


indicates 0.3R, and the labyrinth groove


70


has a semicircular section with a width of 1 mm and a depth of 0.5 mm.




Therefore, even when the piston


53


,


54


is displaced downward by its weight by a gap between the piston


53


,


54


and the liner cylinder


73


A,


74


A to contact the inner surface of the liner cylinder


73


A,


74


A, different from the prior art, the inner surface of the liner cylinder


73


A,


74


A can be prevented from being worn by the tip end peripheral edge


75


of the piston


53


(


54


) and the opening end


76


of the labyrinth groove


70


.




For the present invention with respect to the first constitution in the prior art, a third compression section


103


and fourth compression section


104


are shown, but this is not limited within a technical scope of the present invention.




Next, the present invention with respect to the second constitution of the prior art is shown in

FIGS. 15 and 16

. Specifically, in the compression system high-pressure compressor


100


provided with the compression mechanism for reciprocating/driving the piston


53


(


54


) with respect to the cylinder


73


(


74


) by rotation of the motor and compressing the operating fluid sucked by the driving to generate the high-pressure operating fluid, the compression mechanism is provided with the labyrinth seal structure in which a plurality of labyrinth grooves


70


are formed in the peripheral surface of the piston


53


(


54


), and no lubrication is performed between the piston and the operation inner surface of the cylinder


73


(


74


), that is, the liner cylinder


73


A,


74


A. For a relation between the piston


53


(


54


) and the cylinder


73


,


74


, in a top dead point and a lower dead point in the reciprocating/driving of the piston


53


(


54


), a rear end peripheral edge


78


and a tip end peripheral edge


77


of the piston


53


(


54


) are substantially positioned not to enter the operation inner surface of the cylinder


73


(


74


). Such multistage compression apparatus of the high-pressure compressor is shown.




Therefore, even when the piston


53


(


54


) is displaced downward in top dead point and lower dead point positions, different from the prior art, the phenomenon that the tip and rear ends of the piston


53


,


54


scrape the inner surface of the liner cylinder


73


A,


74


A can be prevented. When the piston


53


,


54


is in the top dead point as shown in

FIG. 15

, the rear end peripheral edge of the piston


53


(


54


) substantially coincides with the rear end of the cylinder


73


(


74


). Moreover, when the piston


53


,


54


is in the lower dead point as shown in

FIG. 16

, the tip end peripheral edge of the piston


53


(


54


) substantially coincides with the tip end of the liner cylinder


73


A,


74


A. Therefore, the length of the liner cylinder


73


A,


74


A can effectively be utilized in a compression stroke and labyrinth seal structure.




For the present invention with respect to the second constitution in the prior art, the third compression section


103


and fourth compression section


104


are shown, but this is not limited within the technical scope of the present invention.




Next, the present invention with respect to the third constitution of the prior art is shown in

FIGS. 17

to


19


. Specifically, in order to omit the piston plate


84


of the prior art, grooves for holding a piston ring


83


and a guide ring


83


A are formed in the peripheral surface inside the peripheral surface of the tip end of a piston


52


. Moreover, in the compression system high-pressure compressor


100


provided with the compression mechanism for reciprocating/driving the piston


52


with respect to a cylinder


72


by rotation of the motor and compressing the operating fluid sucked by the driving to generate the high-pressure operating fluid, the compression mechanism is provided with a non-lubricating seal structure between the operation inner surface of the cylinder


72


and the piston


52


, and further for the piston


52


a tip-end small-diameter portion


93


is formed on a tip end of a large diameter portion


82


. For the cylinder


72


, a small diameter compression section


94


into which the tip end small diameter portion


93


of the piston is substantially tightly inserted when the piston


52


is in the top dead point, and a large diameter portion


96


for forming a compression space


95


in the periphery of the tip end small diameter portion


93


of the piston when the piston


52


is in the lower dead point are continuously formed. This multistage compression apparatus of the high-pressure compressor is shown. As an embodiment, the inner diameter of the small diameter compression section


94


is 75 mm, which is the same as the inner diameter of the prior-art cylinder


72


of FIG.


9


. The inner diameter of the large diameter-compression section


96


is 80 mm, which is larger than the inner diameter of the small diameter compression section


94


by about 10%.




Therefore, the large diameter compression section


96


serves as a first compression section, the small diameter compression section


94


serves as a second compression section and a two-stage compression constitution is formed. Moreover, the presence of the compression space


95


increases a compression capacity, that is, a removal capacity. For example, in a case in which a discharge gas flow rate in one day is increased to 200 Nm


3


/day from 100 Nm


3


/day or in another case, the constitution is effective as a measure for increasing a gas suction amount to increase a gas discharge amount from the compressor. Moreover, since the capacity can be increased without changing the outer diameter of the cylinder


72


, the compressor is not enlarged in size. A tip end peripheral edge


97


of the piston


52


and an inlet peripheral edge


98


of the small diameter compression section


94


of the cylinder


72


are R-chamfered, and biting of the piston


52


and cylinder


72


is prevented.




For the present invention with respect to the third constitution in the prior art, the second compression section


102


is shown, but this is not limited within the technical scope of the present invention. When a first compression section


101


has a single action compression mechanism, the constitution of the present invention can be employed.




Next, the present invention with respect to the fourth constitution of the prior art is shown in

FIGS. 20 and 21

. First in

FIG. 20

, in the compression system high-pressure compressor


100


provided with the compression mechanism for reciprocating/driving the piston


53


,


54


with respect to the cylinder


73


,


74


by rotation of the motor and compressing the operating fluid sucked by the driving to generate the high-pressure operating fluid, the compression mechanism comprises a non-lubricating seal structure between the operation inner surface of the cylinder


73


,


74


, that is, the liner cylinder


73


A,


74


A and the piston


53


,


54


, and the piston


53


,


54


is connected to a connecting rod


85


,


86


by pressing a connecting flange portion


120


extended to the rear end of the piston


53


,


54


in a connection space


121


formed in the connecting rod


85


,


86


by a spring


122


so that the piston


53


,


54


can oscillate with respect to the connecting rod


85


,


86


. This multistage compression apparatus of the high-pressure compressor is shown.




Therefore, by pressing the connecting flange portion


120


into the connection space


121


by the spring, a processing dimension error can be absorbed, a laborious processing for accurately maintaining a processing precision of an engagement/connection portion in the prior art is unnecessary, the necessity of the reinforcing material is obviated, and assembly is facilitated.




For oscillation of the piston


53


,


54


, an abutment surface


120


A of the connecting flange portion


120


pressed onto the connecting rod


85


,


86


has a spherical shape.





FIG. 21

shows another embodiment of the present invention. The embodiment is different from the constitution of

FIG. 20

in that one end of a stable plate


123


for pressing the connecting flange portion


120


is inserted into the spring


122


. This can stabilize the pressing of the connecting flange portion


120


by the spring


122


.




For the present invention with respect to the fourth constitution of the prior art, the third compression section


103


and fourth compression section


104


are shown, but this is not limited within the technical scope of the present invention.




Next, the present invention with respect to the fifth constitution of the prior art is shown in FIG.


22


. Specifically, in the compression type high-pressure compressor provided with the compression mechanism for reciprocating/driving the piston with respect to the cylinder


73


,


74


by rotation of the motor and compressing the operating fluid sucked by the driving to generate the high-pressure operating fluid, the compression mechanism comprises a non-lubricating seal structure between the operation inner surface of the cylinder


73


,


74


, that is, the liner cylinder


73


A,


74


A and the piston


53


,


54


, and a protrusion shape of the tip end of the piston


53


,


54


and an inner surface recess shape of a cylinder head


73


B,


74


B corresponding to the tip end are formed in a substantially identical R shape


123


. The multistage compression apparatus of the high-pressure compressor characterized as described above is shown.




This prevents the phenomenon, caused in the prior art, in which the inner surface of the liner cylinder


73


A,


74


A is scraped by the downward displacement of the piston


53


,


54


, and reliability is enhanced. Moreover, a top clearance between the piston tip end and the cylinder head portion can be minimized, and compression performance can be enhanced.




For the present invention with respect to the fifth constitution of the prior art, the third compression section


103


and fourth compression section


104


are shown, but this is not limited within the technical scope of the present invention.




According to the present invention, there can be provided the multistage compression apparatus of the compression type high-pressure compressor in which prevention of wear of the inner surface of the liner cylinder, increase of the removal capacity, ease of processing, reduction of the top clearance and enhancement of properties, and the like can be realized.




The multistage compression apparatus as another embodiment will next be described. As this multistage compression apparatus, a four-stage compression apparatus is heretofore known and disclosed in U.S. Pat. No. 5,033,940, and the like, in which for example, as shown in

FIG. 25

, four reciprocating compression sections


301


,


302


,


303


,


304


are arranged on axes


305


,


306


crossing at right angles to each other so that the sections reciprocate, pressure is successively raised from the reciprocating compression section


301


and the reciprocating compression section


304


is used as a final-stage high-pressure compression section.




In the four-stage compression apparatus, a pair of opposite pistons


251


,


253


are connected to a yoke


261


A, and a cross slider


262


A disposed movably to cross the axis


306


in the yoke


261


A is connected to a crank shaft


264


via a crank pin


263


. Moreover, another pair of opposite pistons


252


,


254


are connected to a yoke


261


B disposed with a deviation of 90 degrees from the yoke


261


A, and a cross slider (not shown) disposed movably to cross the axis


305


in the yoke


261


B is also connected to the crank shaft


264


via the crank pin


263


.




Therefore, when the crank shaft


264


is rotated by an electric motor (not shown) to rotate the crank pin


263


around the crank shaft


264


, the cross slider


262


A moves to handle the displacement of the crank pin


263


of the direction of the axis


305


in the yoke


261


A, the yoke


261


A moves to handle the displacement of the direction of the axis


306


, and a pair of pistons


251


and


253


therefore reciprocate only in the direction of the axis


306


.




On the other hand, since in the yoke


261


B the cross slider (not shown) moves to handle the displacement of the direction of the axis


306


, the yoke


261


B moves to handle the displacement of the direction of the axis


305


, and a pair of pistons


252


and


254


therefore reciprocate only in the direction of the axis


305


.




Moreover, in order to obtain a smooth reciprocating motion of the pistons


251


,


252


,


253


,


254


from a constant-speed rotation of the crank shaft


264


through conversion, since the cross slider


262


needs to easily slide in the yoke


261


, as shown in

FIG. 26

, a roller bearing


265


is interposed between the yoke


261


and the cross slider


262


.




Moreover, in the piston


254


of the final-stage reciprocating compression section


304


, a plunger piston provided with a labyrinth seal groove (not shown) on the surface is used, and piston rings


251


A,


252


A,


253


A are fitted on the other reciprocating compression section pistons


251


,


252


,


253


to establish a seal with the cylinders.




However, when a bomb as a gas injection tank is charged, for example, with a nitrogen gas pressurized/compressed to a standard of 30 MPa by the four-stage compression apparatus constituted as described above, in the reciprocating compression section


303


for performing third-stage compression, the nitrogen gas of about 3 MPa needs to be pressurized/compressed to indicate about 10 MPa by the piston


253


. However, the piston ring


253


A of the piston


253


is worn, seal property in the reciprocating compression section


303


is deteriorated, and this causes problems: (1) a required high pressure is not obtained; and (2) a required amount of nitrogen gas cannot be supplied.




Specifically, in order to enhance the seal property, a resin piston ring of Teflon hard and superior in lubricating property or the like is used in the piston ring


253


A, but the piston


253


reciprocates while the piston ring


253


A is in contact with a cylinder


201


of the reciprocating compression section


303


, and wear is therefore unavoidable. Therefore, when use time of the piston ring


253


A increases, wear amount increases, a gap is made between the ring and the cylinder


201


of the reciprocating compression section


303


, and the required high pressure cannot be obtained. With the high pressure, there is another problem that a large amount of gas leaks even from a slight gap and a required amount of supply cannot be secured, and it is therefore necessary to prevent the seal property in the third reciprocating compression section


303


from being deteriorated.




Then, the multistage compression apparatus which can solve the aforementioned conventional-art problem will be described with reference to

FIGS. 23

to


26


.





FIG. 23

is an explanatory of the third reciprocating compression section


303


in a four-stage compression apparatus


300


of the present invention for the nitrogen gas. A plunger piston


202


reciprocates/operates inside the cylinder


201


to compress the nitrogen gas sucked into a compression chamber


303


S.




Additionally, the compression chamber


303


S is connected to a compression chamber


302


S of the second reciprocating compression section


302


via a valve mechanism


203


when the plunger piston


202


moves backward and operates to enlarge a capacity of compression chamber


303


S, and connected to a compression chamber


304


S of the fourth reciprocating compression section


304


via a valve mechanism


204


when the plunger piston


202


moves forward and operates to reduce the capacity of the compression chamber


303


S (this operation will be hereinafter referred to as compressing operation).




Moreover, the cylinder


201


and plunger piston


202


are formed so that the gap of the diametric direction is entirely in a range of 3 to 10 μm, pressure loss in the compression chamber


303


S during the compressing operation of the plunger piston


202


is prevented, and the amount of gas leaking from the gap between the cylinder


201


and the plunger piston


202


is reduced to prevent the amount of gas supplied to the compression chamber


304


S of the reciprocating compression section


304


from being insufficient.




The gap of the diametric direction between the cylinder


201


and the plunger piston


202


is preferably small in view of the pressure loss. However, when the gap between the cylinder


201


and the plunger piston


202


formed with a diameter of about 22 mm (additionally, the diameter of the reciprocating compression section


301


is 78 mm, and that of the reciprocating compression section


302


is 39 mm) is set to be smaller than 3 μm, a high precision is required and a manufacture cost disadvantageously increases. Additionally, even with a gap of 3 μm or more the pressurizing/compressing to a predetermined pressure of 30 MPa is sufficiently possible by compression in the fourth reciprocating compression section


304


, and the gap may therefore be 3 μm or more.




On the other hand, even when a labyrinth seal groove


205


is disposed on the surface of the plunger piston


202


as described later, with a large gap of 10 μm or more between the cylinder


201


and the plunger piston


202


, the amount of gas leaking from the gap becomes too large and the amount of gas supplied to the compression chamber


304


S of the fourth reciprocating compression section


304


becomes insufficient. Additionally, the gas cannot be pressurized to a predetermined pressure of about 10 MPa and supplied to the compression chamber


304


S.




Therefore, the cylinder


201


and plunger piston


202


are formed so that the gap of the diametric direction is in a range of 3 to 10 μm as described above.




Moreover, several, for example, seven labyrinth seal grooves


205


are disposed on the surface of the plunger piston


202


at intervals of 4 mm, so that seal effect is enhanced.




Each labyrinth seal groove


205


is disposed so that a depth


200


B is in a range of 0.2 to 0.5 mm, width


200


A is 1.0 mm, and a ratio of depth


200


B/width


200


A is in a range of 0.2 to 0.5.




When the ratio of depth


200


B/width


200


A is less than 0.2, a pressure fluctuation inside the groove is small, eddy does not easily occur and the seal property is disadvantageously deteriorated. When the ratio exceeds 0.5, a flow reducing effect decreases, and the seal property disadvantageously becomes equal to that in a case in which there is no groove. Therefore, the labyrinth seal groove


205


is disposed so that the ratio of depth


200


B/width


200


A is in a range of 0.2 to 0.5.




On the other hand, a cylinder


206


constituting the fourth reciprocating compression section


304


and the plunger piston


254


for reciprocating/operating inside the cylinder to pressurize/compress the nitrogen gas sucked in the compression chamber


304


S are formed so that the gap of the diametric direction is entirely in a range of 2 to 8 μm (see FIG.


25


).




The gap of the diametric direction between the cylinder


206


and the plunger piston


254


is preferably small in view of the pressure loss. However, when the gap between the cylinder


206


and the plunger piston


254


formed with a diameter of about 13 mm is set to be smaller than 2 μm, the high precision is required and the manufacture cost disadvantageously increases. Additionally, even with a gap of 2 μm or more the nitrogen gas pressurized/compressed to about 10 MPa and supplied from the reciprocating compression section


303


can sufficiently be pressurized/compressed to provide a predetermined pressure of 30 MPa, and the gap may therefore be 2 μm or more.




However, when a gap larger than 8 μm is present between the cylinder


206


and the plunger piston


254


, even with the labyrinth seal groove disposed on the surface of the plunger piston


254


, the amount of gas leaking from the gap becomes too large, the nitrogen gas cannot be pressurized/compressed to the predetermined pressure of about 30 MPa, and it is disadvantageously impossible to supply a predetermined amount of high-pressure nitrogen gas within a predetermined time.




Therefore, the cylinder


206


and plunger piston


254


are formed so that the gap of the diametric direction is in a range of 2 to 8 μm as described above.




Moreover, several labyrinth seal grooves (not shown) are also disposed on the surface of the plunger piston


254


, so that the seal effect with the cylinder


206


is enhanced.




Furthermore, by setting the gap of the diametric direction between the cylinder


206


of the fourth reciprocating compression section


304


and the plunger piston


254


to be smaller than the gap between the cylinder


201


of the third reciprocating compression section


303


and the plunger piston


202


, the pressure loss and the increase of the amount of leaking gas are prevented.




Additionally, other constitutions are substantially the same as those of the conventional multistage compression apparatus shown in

FIGS. 25

,


26


.




Therefore, according to the four-stage compression apparatus of the present invention constituted as described above, when the nitrogen gas is successively pressurized/compressed in the compression chamber


301


S of the reciprocating compression section


301


, the compression chamber


302


S of the reciprocating compression section


302


, the compression chamber


303


S of the reciprocating compression section


303


, and the compression chamber


304


S of the reciprocating compression section


304


to charge the bomb for gas injection or the like, during the pressurizing/compressing in the compression chamber


303


S of the reciprocating compression section


303


and the compression chamber


304


S of the reciprocating compression section


304


having reached the high pressure, the amount of nitrogen gas leaking from the gap between the cylinder and plunger piston is reduced, the predetermined high pressure is easily obtained, and charging time is shortened.




Additionally, since the present invention is not limited to the aforementioned embodiment, various modifications are possible without departing from the scope defined in the appended claims.




As described above, according to the multistage compression apparatus of the present invention, the gas leak mainly in the latter-stage compression section in which the predetermined high pressure is obtained can be prevented, and therefore the nitrogen gas can quickly be pressurized/compressed, for example, to a high pressure of 30 MPa and supplied.




The multistage compression apparatus as still another embodiment will next be described. For the multistage compression apparatus, in the conventional art, when the gas bomb of a natural gas car is charged with operating fluids such as a natural gas, the operating fluid is compressed to the high pressure by the multistage compression apparatus and the charging is performed.




Various constitutions are proposed with respect to the multistage compression apparatus, and a constitution shown in

FIG. 31

is one of the proposals. Additionally,

FIG. 32

is a top plan view.




In the multistage compression apparatus, compression means


502


is disposed in an upper part, and driving means


503


contained in a sealed case


504


is disposed in a lower part.




A space in the case


504


is connected to a back pressure chamber in the compression means


502


. The operating fluid sucked via an inlet port


510


is compressed in the compression chamber and discharged to the outside of the apparatus via a discharge port


514


.




The compression means


502


is constituted of first to fourth compression sections


500


A,


500


B,


500


C,


500


D for compressing the operating fluid, and disposed in a cross position. Additionally, the first to fourth compression sections


500


A to


500


D are provided with first to fourth pistons (not shown), respectively.




The operating fluid is compressed in the first compression section


500


A and fed to the second compression section


500


B, and compressed in the second compression section


500


B and fed to the third compression section


500


C. The operating fluid is successively compressed in this manner and fed to the fourth compression section


500


D, and finally compressed in the fourth compression section


500


D and discharged from the discharge port


514


.




In this case, when the operating fluid of each compression chamber flows to the side of the back pressure chamber via the space between the piston and the piston cylinder for containing the piston, the compression efficiencies of the respective compression sections


500


A to


500


D are deteriorated.




Additionally, in the following description, the space between the piston and the piston cylinder is referred to as a clearance, and the operating fluid flowing to the side of the back pressure chamber through the clearance is referred to as a piston leak. Therefore, the piston leak flows along the side surface (sliding surface) of the piston.




In this case, the first to third pistons are provided, for example, with contact type seals such as an O ring, and a fourth piston


521


of a final stage is provided with a labyrinth seal


523


as a non-contact type seal as shown in

FIG. 33

so that the piston leak is inhibited.




The labyrinth seal


523


shown in

FIG. 33

is an annular groove (hereinafter referred to as a labyrinth groove) with a groove depth of about several hundreds of microns formed in the sliding surface of the fourth piston


521


, and a plurality of labyrinth grooves are formed at equal intervals to enhance the seal property.




On the other hand, a relief valve


505


is attached to the side surface of the case


504


. The relief valve


505


is disposed to avoid the following unexpected situation. The pressure in the case


504


sometimes becomes abnormally high for an unexpected reason. If this state is left to stand, the case


504


is deformed or cracked.




Specifically, when the pressure in the case


504


reaches the predetermined pressure, the relief valve


505


is opened to prevent the aforementioned unexpected situation.




However, in order to enhance the seal property of the labyrinth seal


523


, it is necessary to increase the number of labyrinth grooves and to increase a forming density of labyrinth grooves, but when the number of labyrinth grooves and the density of the labyrinth grooves are increased, there is a problem that a labyrinth groove forming cost raises a product cost.




Moreover, since the labyrinth grooves are disposed at equal intervals, the length of the fourth piston


521


necessarily determines the number of labyrinth grooves which can be formed, and it is disadvantageously difficult to achieve a higher seal property.




On the other hand, when the multistage compression apparatus is used for a long time, the contact type seals such as the O ring disposed on the first to third pistons and the movable portion of the piston shaft are gradually worn, and moisture contained in the operating fluid is condensed and formed into waterdrops in some cases.




Since the worn powder, waterdrops, and the like are accumulated in the bottom of the case


504


, to remove these the multistage compression apparatus has to be disassembled/cleaned, which raises a problem in ease of maintenance.




To solve the problem, according to the present invention, there is provided a multistage compression apparatus in which the piston leak can more efficiently be reduced without increasing the number of labyrinth grooves, and the maintenance is easily performed. The apparatus will be described with reference to

FIGS. 27

to


30


.

FIG. 27

is a partially broken side view of the multistage compression apparatus of the present invention,

FIG. 28

is a horizontal sectional view of the compression means, and

FIG. 29

is a side view of the fourth piston.




In the multistage compression apparatus, compression means


402


is disposed in an upper part, and driving means


403


contained in a sealed case


404


is disposed in a lower part.




The operating fluid such as the natural gas supplied via a suction port


410


is supplied to a space in the case


404


, and the space in the case


404


is connected to a back pressure chamber


411


which also serves as an operating fluid supply chamber in the compression means


402


.




Subsequently, the operating fluid supplied to the compression chamber from the back pressure chamber


411


is compressed in the compression chamber and discharged to the outside of the apparatus via a discharge port


414


.




Additionally, a bottom


406


of the case


404


is provided with a relief valve


405


in a vertical downward direction.




The compression means


402


is constituted by disposing first to fourth compression sections A to D for compressing the operating fluid in a cross position, and the first to fourth compression sections A to D are provided with first to fourth pistons


421


A to


421


D, respectively.




The first piston


421


A is connected to the third piston


421


C via a piston shaft


412


, the second piston


421


B is connected to the fourth piston


421


D via a piston shaft


413


, and the respective pistons cooperatively operate to reciprocate in the same direction.




The piston shafts


412


,


413


are disposed on the side of the back pressure chamber


411


of the respective pistons


421


A to


421


D.




The first piston


421


A is provided with a suction port (not shown) for connecting the back pressure chamber


411


to a first compression chamber


422


A, and a suction side check valve (not shown) is disposed midway in the suction port.




Moreover, respective compression chambers


422


A to


422


D are connected via a connecting pipe


430


, and the connecting pipe


430


is provided with suction and discharge side check valves (not shown).




Phases of the respective pistons


421


A to


421


D are delayed every 45 degrees toward the later-stage compression section like the first compression section A second compression section B→compression section C→fourth compression section D, and diameters of the respective pistons


421


A to


421


D are reduced toward the later stage. Therefore, the respective compression chambers


422


A to


422


D are also reduced in size.




Moreover, when the first piston


421


A moves toward the back pressure chamber


411


, the suction side check valve opens, the operating fluid on the side of the back pressure chamber


411


is taken into the first compression chamber


422


A and compressed. Of course, the suction side check valve is closed during compression.




Therefore, the operating fluid is compressed by the first compression section A and fed to the second compression section B, and compressed in the second compression section B and fed to the third compression section C. The operating fluid is successively compressed in this manner and fed to the fourth compression section D, and finally compressed in the fourth compression section D and discharged from the discharge port


414


.




In this case, in order to inhibit the piston leak caused when the operating fluid of each of the compression chambers


422


A to


422


D flows via the clearance, the first, second pistons


421


A,


421


B are provided, for example, with contact type seals


423


A,


423


B such as O rings, and the third, fourth pistons


421


C,


421


D are constituted of plunger pistons provided with labyrinth seals


423


C,


423


D as shown in FIG.


29


.




The labyrinth seal


423


D of the fourth piston


421


D shown in

FIG. 29

is formed on the sliding surface of the fourth piston


421


D and is a labyrinth groove formed of an annular groove with a groove depth of about several hundreds of microns, and the density of labyrinth grooves is reduced toward the side of the back pressure chamber


411


from the side of the fourth compression chamber


422


D.




Additionally, in the present specification, a uniform density of labyrinth grooves is referred to as “equal pitch”, and the density with a change is referred to as “irregular pitch”.





FIG. 30

is a chart showing comparison of the seal property between the equal pitch (solid line) and the irregular pitch (dotted line) when the number of labyrinth grooves is the same, the ordinates indicates a flow rate of the operating fluid, and the abscissa indicates a distance of the fourth compression chamber


422


D from a piston operation surface. In the present embodiment, the pitch interval indicates a coarse density in arithmetical series toward the side of the back pressure chamber


411


from the side of the fourth compression chamber


422


D.




The labyrinth groove closest to the side of the back pressure chamber


411


has an unevenness of about 0.242 mm, and an area P in

FIG. 30

indicates the flow rate in a clearance area between the labyrinth groove and the back pressure chamber


411


.




It is seen from

FIG. 30

that with the irregular pitch the flow rate can be reduced at least in the area P. Additionally, since the clearance is the same in either the equal pitch or the irregular pitch, the reduction of the flow rate means the inhibition of the piston leak.




The irregular pitch inhibits the piston leak in this manner supposedly for the following reason.




The leak is usually generated when the operating fluid flows to a low pressure side from a high pressure side, and a leak amount is substantially defined by a pressure difference and conductance. Specifically, even in the same leak path, when the pressure difference is large, the leak amount increases. Moreover, even with the same pressure difference, when the conductance is small, the leak amount increases.




In the present invention, the pressure difference indicates a difference pressure between the fourth compression chamber


422


D and the back pressure chamber


411


. Moreover, the conductance can be interpreted as an inverse number of flow resistance when the operating fluid flows to the back pressure chamber


411


from the fourth compression chamber


422


D, and to reduce the conductance the number of labyrinth grooves or the density may be increased.




Moreover, the labyrinth seal


423


D is constituted when the operating fluid flowing through the clearance is expanded in the labyrinth groove, the pressure difference from the adjacent labyrinth groove on the low pressure side is reduced and this depresses the flow rate of the operating fluid.




Therefore, it is interpreted that by increasing the density of labyrinth grooves on the side of the fourth compression chamber


422


D as compared with that on the side of the back pressure chamber


411


, pressure drop is efficiently (rapidly) generated in the high density area and the piston leak is inhibited.




This means that the conductance of the fourth compression chamber


422


D and back pressure chamber


411


substantially becomes small, and it is seen that the effect similar to the effect obtained by increasing the number and forming density of the labyrinth grooves can be obtained by the aforementioned irregular pitch.




Moreover, also when the plunger piston is used in the third compression chamber, the similar effect can be obtained using the labyrinth seal with the similar irregular pitch.




The maintenance of the multistage compression apparatus constituted as described above will next be described. The multistage compression apparatus is provided with a plurality of movable portions as described above, with the operation the movable portions are worn and the worn powder is accumulated in the bottom


406


of the case


404


. Moreover, when the operating fluid contains moisture, the moisture is condensed in the case


404


to form waterdrops, and accumulated in the bottom of the case


404


. Furthermore, in the conventional art these are removed by disassembling/cleaning.




In the present invention, however, the relief valve


405


is disposed in the bottom


406


of the case


404


and directed downward. Therefore, when the worn powder, and the like are accumulated, the pressure in the case


404


is manually raised to open the relief valve


405


, and the worn powder, and the like are discharged together with the operating fluid to the outside of the apparatus.




Of course, when the pressure in the case


404


abnormally rises for the unexpected reason-, the relief valve


405


is also opened, and needless to say, the worn powder, and the like are discharged to the outside of the apparatus.




Therefore, the inside of the case


404


can be cleaned without disassembling the case and a maintenance property is considerably enhanced.




Additionally, in the above description, it is premised that the multistage compression apparatus is constituted of an oil-less mechanism, but the present invention is not limited to this.




In this case, by disposing the relief valve


405


on the bottom


406


, when the relief valve


405


is opened, oil is discharged to the outside of the apparatus, which produces a fear that the outside of the apparatus is contaminated and oil is wasted.




To solve the problem that the outside of the apparatus is contaminated, a storage tank (not shown) for storing the oil discharged from the relief valve


405


may separately be disposed.




Moreover, the problem that the oil is wasted is essentially nonsense as described later. Specifically, when the oil containing the worn powder, and the like is continuously used as a lubricant, the worn powder adheres to the movable portion and, for example, a serious trouble that the piston is locked occurs. Therefore, even during disassembling/cleaning the oil has to be changed.




As described above, since the forming density of labyrinth grooves is reduced toward the side of the back pressure chamber from the side of the compression chamber, the seal property can efficiently be enhanced.




Moreover, since the relief valve is disposed in the bottom of the sealed case, the worn powder of the movable portion, and the like can be discharged to the outside of the apparatus via the relief valve without disassembling/cleaning the apparatus, and the maintenance property is enhanced.




The multistage compression apparatus as still another embodiment will next be described. As the multistage compression apparatus, in a conventional constitution, with an increase of the number of compression stages, the reciprocating compression sections, that is, the compression sections formed by cylinders and pistons are disposed so that diameters of the cylinder and piston are reduced toward the high pressure side, and are arranged in an L type, V type, W type, semi-star type, star type, opposite balance type, and the like, and the respective compression sections are cooperatively connected via the crank shaft so that the sections operate in strokes deviating by the required phase to perform a multistage compressing operation in a mechanism. A constitution for operating this mechanism by driving sources such as an electric motor is disclosed (

FIGS. 30

to


32


, and the like of the tenth edition of “Mechanical Engineering Handbook” by the Japan Society of Mechanical Engineers as of Sep. 15, 1970).




Moreover, as shown in

FIG. 42

, a conventional multistage compression apparatus


700


is known in which four reciprocating compression sections


701


,


702


,


703


,


704


are arranged on axes


705


,


706


crossing at right angles to each other so that the sections reciprocate/cooperate, the pressure is successively raised from the reciprocating compression section


701


and the reciprocating compression section


704


is used as the high-pressure compression section of the final stage.




Moreover, in the multistage compression apparatus


700


, a pair of opposite pistons


651


,


653


are connected to a yoke


601


A, another pair of opposite pistons


652


,


654


are connected to a yoke


601


B which deviates from the yoke


601


A by 90 degrees, a crank shaft


655


is rotated by an electric motor of an electromotive section (not shown) to rotate a crank pin


656


around the crank shaft


655


, the pair of pistons


651


,


653


are reciprocated only in the direction of the axis


706


, and the other pair of pistons


652


,


654


are reciprocated only in the direction of the axis


705


. In this example, the fourth reciprocating compression section


704


is constituted by a plunger pump.




In the conventional constitution, the reciprocating compression section


704


is constituted by inserting the piston


654


into the cylinder


658


. Since the cylinder


658


is formed of ceramic in view of a linear expansion coefficient, surface finishing, and the like, there is a problem that pressure resistant strength is weak. As additional problems, vibration occurs, the cylinder


658


moves and is damaged, gap precision between the cylinder


658


and the piston


654


is deteriorated and performance and reliability are deteriorated.




Then, according to the present invention, with respect to the multistage compression apparatus in which at least one reciprocating compression section for compressing required gasses such as the nitrogen gas in multiple stages to the high pressure is constituted by the plunger pump, there is provided a multistage compression apparatus in which the pressure resistant strength of the cylinder of the plunger pump is enhanced to solve the conventional plunger pump problems that the vibration occurs, the cylinder moves and is damaged, the gap precision between the cylinder and the piston is deteriorated and the performance is deteriorated, so that the durability and reliability are enhanced. Moreover, with respect to the piston (e.g., piston


51


) provided with the piston ring and guide ring, there is provided a multistage compression apparatus in which PV value of the piston ring or the guide ring is reduced, mechanical loss is reduced, and reliability is enhanced.




The embodiment of the present invention will be described hereinafter with reference to

FIGS. 34

to


40


.

FIG. 34

is an explanatory view showing a section of still another embodiment of the multistage compression apparatus of the present invention,

FIG. 35

is an explanatory view showing a section of the fourth reciprocating compression section (plunger pump) of the multistage compression apparatus of the present invention shown in

FIG. 34

, and

FIG. 36

is an explanatory view showing a section of the third reciprocating compression section (plunger pump) of the multistage compression apparatus of the present invention shown in FIG.


34


.




Additionally, in these drawings the components denoted by the same reference numerals as those of

FIG. 42

have functions similar to those described in the related art, and the description thereof is omitted as long as understanding of the present invention is not hindered.




As shown in

FIG. 35

, the fourth reciprocating compression section (plunger pump)


704


of a multistage compression apparatus


700


A of the present invention shown in

FIG. 34

is constituted of the piston


654


inserted into a ceramic cylinder liner


601


, a connecting rod


602


connected to the piston


654


(connecting rod for connecting the piston


654


to the yoke


601


B), and the like, and a sleeve


604


is interposed as the pressure resistant structure member between the cylinder liner


601


and a plunger pump main body


603


. Moreover, the cylinder liner


601


and sleeve


604


are fixed by screwing a fixing bolt


605


into the plunger pump main body


603


.




As shown in

FIG. 36

, the third reciprocating compression section (plunger pump)


703


of the multistage compression apparatus


700


A of the present invention shown in

FIG. 34

is constituted of the piston


653


inserted into a ceramic cylinder liner


601




a


, a connecting rod


602




a


connected to the piston


653


(connecting rod for connecting the piston


653


to the yoke


601


A), and the like, and a sleeve


604




a


is interposed as the pressure resistant structure member between the cylinder liner


601




a


and a plunger pump main body


603




a


. Moreover, the cylinder liner


601




a


and sleeve


604




a


are fixed by screwing a fixing bolt


605




a


into the plunger pump main body


603




a.






As shown in

FIGS. 35

,


36


, since the sleeves


604


,


604




a


are interposed as the pressure resistant structure members, and the cylinder liners


601


,


601




a


and sleeves


604


,


604




a


are fixed to the plunger pump main bodies


603


,


603




a


by the fixing bolts


605


,


605




a


, pressure resistant strengths of the ceramic cylinder lines


601


,


601




a


can be enhanced. Additionally, according to the plunger pump constituted as described above, there can be provided a multistage compression apparatus which solves the problems that the vibration occurs, the cylinder liner


601


,


601




a


moves and is damaged, the gap precision between the cylinder


601


,


601




a


and the piston


654


,


653


is deteriorated and the performance is deteriorated, and which enhances the durability and reliability.





FIG. 37

is an explanatory view showing a section of still another embodiment of the fourth reciprocating compression section of the multistage compression apparatus of the present invention. As shown in

FIG. 37

, a fourth reciprocating compression section (plunger pump)


704




a


of this example is constituted similarly as the fourth reciprocating compression section


704


shown in

FIG. 35

, except that an elastic cushion member


607


such as a leaf spring is interposed and attached between a connecting rod sleeve


606


into which the connecting rod


602


is inserted and the fixing bolt


605


. Since the elastic cushion member


607


such as the leaf spring is interposed and attached between the connecting rod sleeve


606


and the fixing bolt


605


, the motion of the cylinder liner


601


or the sleeve


604


is further inhibited, the vibration is reduced, and the reliability is further enhanced.





FIG. 38

is an explanatory view showing a section of still another embodiment of the fourth reciprocating compression section of the multistage compression apparatus of the present invention. As shown in

FIG. 38

, in a fourth reciprocating compression section (plunger pump)


704




b


of this example, one pressure release groove


608


(see

FIG. 39

) is disposed through a thickness direction of a sleeve


604




b


in a surface by which the sleeve


604




b


as the pressure resistant structure member is in contact with the fixing bolt


605


. Moreover, a connecting rod sleeve


606




a


is provided with two pressure release holes


609


passed downward from above through the connecting rod sleeve


606




a.







FIG. 39A

shows a longitudinal section of the sleeve


604




b


, and

FIG. 39B

shows the pressure release groove


608


disposed through the thickness direction of the sleeve


604




b


in the surface by which the sleeve


604




b


is in contact with the fixing bolt


605


. Numeral


610


denotes an annular groove disposed in the inner wall surface of the sleeve


604




b.






A gas between the sleeve


604




b


and the plunger pump main body


603


is passed through the pressure release groove


608


, and subsequently passed through the pressure release holes


609


to escape into the multistage compression apparatus of the present invention as shown by arrows. Moreover, the gases between the cylinder liner


601


and the sleeve


604




b


and between the connecting rod


602


and the connecting rod sleeve


606




a


are similarly passed through the pressure release holes


609


to escape into the multistage compression apparatus of the present invention. This can prevent the pressure behind the cylinder from rising, and can also prevent the pressure between the connecting rod


602


and the connecting rod sleeve


606




a


from rising, the piston


654


smoothly moves, inputs are therefore reduced, biting of the piston


654


is prevented, and the reliability is enhanced.





FIG. 41

is an explanatory view showing a section of the conventional piston (e.g., the piston


651


of

FIG. 42

) provided with the piston ring and guide ring. As shown in

FIG. 41

, a piston ring


611


and a guide ring


612


are just fitted in a piston ring groove


611




a


and a guide ring groove


612




a


formed in the piston


651


.





FIG. 40

is an explanatory view showing a section of a piston


651




a


provided with the piston ring and guide ring for use in the present invention. As shown in

FIG. 40

, the piston ring


611


is fitted in a piston ring groove


611




b


provided with a width larger than that of the piston ring


611


. The guide ring


612


is just fitted in the guide ring groove


612




a.






In this constitution, when the piston


651




a


reciprocates, the piston ring


611


also reciprocates in the piston ring groove


611




b


as shown by an arrow, a load on the piston ring


611


can be reduced, the PV value can be reduced as compared with the piston


651


shown in

FIG. 41

, and the mechanical loss can be reduced. The guide ring


612


and guide ring groove


612




a


can also be constituted similarly as the piston ring


611


and piston ring groove


611




b.






Additionally, since the present invention is not limited to the aforementioned embodiment, various modifications are possible without departing from the scope defined by the appended claim.




For example, a plurality of reciprocating compression sections may be arranged in the L type, V type, W type, semi-star type, star type, opposite balance type, and the like as described above, or three or five or more reciprocating compression sections may be arranged in the star type in the multistage compression apparatus.




Therefore, by interposing the sleeve as the pressure resistant structure member between the cylinder liner and the plunger pump main body, and fixing the cylinder liner and sleeve to the plunger pump main body via the fixing bolt, the pressure resistant strength of the cylinder of the plunger pump is enhanced, and there can be provided the multistage compression apparatus which can solve the problems that the vibration occurs, the cylinder moves and is damaged, the gap precision between the cylinder and the piston is deteriorated and the performance is deteriorated, and which therefore enhances the durability and reliability.




By interposing and attaching the elastic cushion member such as the leaf spring between the connecting rod sleeve into which the connecting rod is inserted and the fixing bolt, the motion of the cylinder liner and sleeve is further inhibited, the vibration is reduced, and the reliability is further enhanced.




By disposing one or two or more pressure release grooves through the thickness direction in the surface by which the sleeve as the pressure resistant structure member contacts the fixing bolt, the pressure behind the cylinder can be prevented from rising, the input is reduced, the biting of the piston is prevented and the reliability is enhanced.




By disposing one or two or more pressure release holes through the connecting rod sleeve, the pressure between the connecting rod sleeve and the connecting rod can be prevented from rising and the piston smoothly moves, so that the input reduction is realized, the biting of the piston is prevented and the reliability is enhanced.




During attaching of the piston ring and guide ring, by setting either one or both of the piston ring groove and the guide ring groove disposed in the piston to be larger in width than the ring itself, the PV value of the piston ring or the guide ring can be reduced, and the mechanical loss can be reduced.




The multistage compression apparatus as still further embodiment will next be described. Here, the conventional multistage compression apparatus will be described with reference to FIG.


42


. In the multistage compression apparatus


700


, a pair of opposite pistons


651


,


653


are connected to the yoke


601


A, and a cross slider


602


A disposed movably to cross the axis


706


in the yoke


601


A is connected to the crank shaft


655


via the crank pin


656


. Moreover, another pair of opposite pistons


652


,


654


are connected to the yoke


601


B disposed to deviate from the yoke


601


A by 90 degrees, and a cross slider


602


B disposed movably to cross the axis


705


in the yoke


601


B is connected to the crank shaft


655


via the crank pin


656


.




Moreover, when the crank shaft


655


is rotated by the electric motor (not shown) to rotate the crank pin


656


around the crank shaft


655


, in the yoke


601


A the cross slider


602


A moves to handle the displacement of the crank pin


656


of the direction of the axis


705


, and the yoke


601


A moves to handle the displacement of the direction of the axis


706


, and a pair of pistons


651


,


653


therefore reciprocate only in the direction of the axis


706


.




On the other hand, since in the yoke


601


B the cross slider


602


B moves to handle the displacement of the direction of the axis


706


, and the yoke


601


B moves to handle the displacement of the direction of the axis


705


, a pair of pistons


652


,


654


reciprocate only in the direction of the axis


705


.




Moreover, in order to obtain the smooth reciprocating motion of the pistons


651


,


652


,


653


,


654


from the constant-speed rotation of the crank shaft


655


through conversion, the cross slider


602


A needs to easily slide in the yoke


601


A, and the cross slider


602


B needs to easily slide in the yoke


601


B. For this purpose, the sliding portion is charged with grease and used.




However, in the multistage compression apparatus


700


, since the sliding portion of the yoke


601


A and cross slider


602


A and the sliding portion of the yoke


601


B and cross slider


602


B are opened, the grease flies during operation, and there is a problem that the grease is insufficiently supplied to the sliding portion. When the grease supply to the sliding portion becomes insufficient in this manner, in long-period operation the vibration, wear, and the like cannot be inhibited, and the reliability is deteriorated.




On the other hand, in the multistage compression apparatus in which no piston is disposed in an opposite position, oscillation easily occurs with the shaft of the piston disposed opposite to the aforementioned position during operation, the occurrence of oscillation of the piston shaft results in averse influences such as biting and the reliability is disadvantageously deteriorated.




In this case, according to the present invention, there is provided a highly reliable multistage compression apparatus for compressing the required gas such as the nitrogen gas in multiple stages to the high pressure, in which the grease flying during operation is prevented, and the vibration, noise, wear, and the like are inhibited, and further there is provided a highly reliable multistage compression apparatus in which even when no piston is disposed in the opposite position, the oscillation of the piston shaft is inhibited from occurring during operation.




The embodiment of the present invention will be described hereinafter in detail with reference to

FIGS. 43

to


47


.

FIG. 43

is an explanatory view showing a main part of the embodiment of the multistage compression apparatus of the present invention,

FIG. 44

is an explanatory view showing the yoke, cross slider, and the like of the multistage compression apparatus of the present invention,

FIG. 45

is an explanatory view showing a partial section of the yoke, cross slider, and the like of the multistage compression apparatus of the present invention shown in

FIG. 43

,

FIG. 46

is a side view of the yoke shown in

FIG. 45

, and

FIG. 47

is an explanatory view showing a main part of another multistage compression apparatus of the present invention.




In a multistage compression apparatus


900


A of the present invention shown in

FIG. 43

, four reciprocating compression sections


901


,


902


,


903


,


904


are arranged to reciprocate/cooperate on axes


905


,


906


crossing at right angles to each other, the gas compressed in the respective reciprocating compression sections is transferred via pipelines


805


to


808


to successively raise the pressure in order from the reciprocating compression section


901


to the reciprocating compression section


904


, and a cover


810


provided with an opening


809


in a middle portion is fixed and disposed to sandwich yokes


801


A and


801


B. The yoke


801


A will be described hereinafter, but the yoke


801


B is similar to the yoke


801


A.




As shown in

FIGS. 44

to


46


, the opening


809


of the cover


810


is disposed in the middle portion so that during apparatus operation an end of the opening


809


is prevented from contacting a crank pin


803


or hindering the motion of the crank pin


803


. As shown in

FIG. 46

, the portion of the cover


810


other than the opening


809


is fixed and disposed to cover an opening in the yoke


801


A and sandwich the yoke


801


A.




A material of the cover


810


may be a metal, a nonmetal such as ceramic, FRP, and engineering plastic, or a combination of these, and is not particularly limited. Since engineering plastic is provided with physical and mechanical properties so that it can bear temperature and pressure during the apparatus operation, and is resistant to the compressed gas and grease, it can preferably be used.




In

FIG. 45

numeral


811


denotes a roller bearing,


812


denotes a liner plate,


813


denotes a spring, and


814


denotes a fixing member. The roller bearing


811


is disposed to press opposite side surfaces of a cross slider


802


A by an elastic force of the spring


813


exerted via the liner plate


812


and assists the sliding of the cross slider


802


A in the yoke


801


A.




In the multistage compression apparatus


900


A of the present invention, since the cover


810


is fixed and disposed to sandwich the yokes


801


A and


801


B, the grease can be inhibited from flying from the yokes


801


A and


801


B during the apparatus operation. In the multistage compression apparatus


900


A of the present invention since the grease is sufficiently supplied to the sliding portions in the yokes


801


A and


801


B, the vibration, noise, wear, and the like can be inhibited even in the long-period operation, and the reliability is enhanced.




When the cover


810


is shrink-fitted and fixed to the yokes


801


A and


801


B, the cover


810


is easily assembled, and additionally the cover


810


can firmly be disposed and prevented from dropping, so that the reliability is further enhanced.




A multistage compression apparatus


900


B (three-stage compression apparatus) of the present invention shown in

FIG. 47

is provided with no piston in a position


904


A opposite to a piston


852


of the reciprocating compression section


902


. Pistons


851


,


853


of the three reciprocating compression sections


901


,


902


,


903


reciprocate only in the direction of the axis


905


, the piston


852


and a connecting rod


854


A are arranged to reciprocate/cooperate on the axis


906


, and the pressure is successively raised from the reciprocating compression section


901


to the reciprocating compression section


903


to set the reciprocating compression section


903


as the high-pressure compression section of the final stage in the multistage compression apparatus. The connecting rod


854


A is fixed to the yoke


801


B in the position


904


A opposite to the piston


852


, and the connecting rod


854


A is disposed in a cylinder


815


for guiding the rod so that the rod can reciprocate.




As described above, in the multistage compression apparatus


900


B, a pair of opposite pistons


851


,


853


are connected to the yoke


801


A, and another pair of piston


852


and connecting rod


854


A are connected to the yoke


801


B disposed to deviate from the yoke


801


A by 90 degrees, a crank shaft


804


is rotated by the electric motor (not shown) to rotate a crank pin


803


around the crank shaft


804


, the pair of pistons


851


,


853


are reciprocated only in the direction of the axis


905


, and the other pair of piston


852


and connecting rod


854


A are reciprocated only in the direction of the axis


906


.




For the multistage compression apparatus


900


B of the present invention, similarly as the multistage compression apparatus


900


A of the present invention, since the cover


810


is fixed and disposed to sandwich the yokes


801


A and


801


B, the grease flying during the apparatus operation can be inhibited and the grease supply to the sliding portion becomes sufficient. Therefore, even in the long-period operation the vibration, noise, wear, and the like can be inhibited, and the reliability is enhanced. Moreover, since the connecting rod


854


A is fixed to the yoke


801


B, and the cylinder


815


for guiding the connecting rod


854


A so that the rod can reciprocate is disposed, during the operation the oscillation of the shaft of the piston


852


opposite to the connecting rod


854


A can be prevented from occurring, no biting occurs, the operation can steadily be performed and the reliability is further enhanced.




Additionally, since the present invention is not limited to the aforementioned embodiment, various modifications are possible without departing from the scope defined in the appended claims.




For example, a plurality of reciprocating compression sections may be arranged in the L type, V type, W type, semi-star type, star type, opposite balance type, and the like as described above, or three or five or more reciprocating compression sections may be arranged in the star type in the multistage compression apparatus.




By the aforementioned constitution, in the multistage compression apparatus of the present invention in which the cover provided with the opening in the middle portion not to hinder the crank pin motion is fixed and disposed to sandwich the yoke, during the operation the grease can be inhibited from flying from the yoke, the supply of the grease to the cross slider sliding portion becomes sufficient, the vibration, noise, wear, and the like can be inhibited even in the long-period operation, and the reliability is high.




It is preferable to shrink-fit and fix the cover to the yoke, in this case the cover is easily assembled, and additionally the cover can firmly be fixed to the yoke and prevented from dropping, so that the reliability is further enhanced.




Even when at least one pair is provided with no piston in the opposite position, by disposing the connecting rod fixed to the yoke, and the cylinder for guiding the connecting rod so that the connecting rod can reciprocate in the position, the oscillation of the shaft of the piston opposite to the connecting rod can be prevented from occurring, and the reliability is enhanced.




The multistage compression apparatus as still another embodiment will next be described. As the conventional multistage compression apparatus, as shown in

FIG. 51

, a multistage compression apparatus


1100


is known in which four reciprocating compression sections


1101


,


1102


,


1103


,


1104


are arranged to reciprocate/cooperate on axes


1105


,


1106


crossing at right angles to each other, the pressure is successively raised from the reciprocating compression section


1101


and the reciprocating compression section


1104


is set as the high-pressure compression section of the final stage.




Moreover, in the multistage compression apparatus


1100


, a pair of opposite pistons


1051


,


1053


are connected to a yoke


1001


A, and a cross slider


1002


A disposed movably to cross the axis


1106


in the yoke


1001


A is connected to a crank shaft


1004


via a crank pin


1003


. Moreover, another pair of opposite pistons


1052


,


1054


are connected to a yoke


1001


B disposed to deviate from the yoke


1001


A by 90 degrees, and a cross slider (not shown) disposed movably to cross the axis


1105


in the yoke


1001


B is also connected to the crank shaft


1004


via the crank pin


1003


.




Furthermore, when the crank shaft


1004


is rotated by the electric motor (not shown) to rotate the crank pin


1003


around the crank shaft


1004


, in the yoke


1001


A the cross slider


1002


A moves to handle the displacement of the crank pin


1003


of the direction of the axis


1105


, the yoke


1001


A moves to handle the displacement of the direction of the axis


1106


, and the pair of pistons


1051


,


1053


therefore reciprocate only in the direction of the axis


1106


.




On the other hand, in the yoke


1001


B the cross slider (not shown) moves to handle the displacement of the direction of the axis


1106


, the yoke


1001


B moves to handle the displacement of the direction of the axis


1105


, and the pair of pistons


1052


,


1054


reciprocate only in the direction of the axis


1105


.





FIG. 50

is an explanatory view showing a sectional structure of the first reciprocating compression section


1101


of the multistage compression apparatus


1100


. The piston


1051


of the first reciprocating compression section


1101


moves backward, valves


10




c


,


10




d


close, valves


10




a


,


10




b


open and a gas is sucked into a compression chamber


1056


in a cylinder


1055


via the valves


10




a


,


10




b


from directions shown by arrows, then the piston


1051


advances to close the valves


10




a


,


10




b


, the gas is compressed in the compression chamber


1056


and reaches the predetermined pressure to open the valves


10




c


,


10




d


, the gas is discharged from the compression chamber


1056


via the valves


10




c


,


10




d


in directions shown by arrows, and the gas is fed to the second reciprocating compression section


1102


(not shown). Numeral


1057


is a connecting rod for connecting the piston


1051


to the yoke


1001


A.




In the multistage compression apparatus


1100


, for example, it is requested that the discharge amount can efficiently be increased without increasing the diameter of the cylinder


1055


of the first reciprocating compression section


1101


.




Then, according to the present invention, in the multistage compression apparatus for compressing required gases such as a nitrogen gas in multiple stages to the high pressure, for example, the discharge amount can efficiently be increased without enlarging the diameter of the cylinder of the first reciprocating compression section.




The embodiment of the present invention will be described hereinafter in detail with reference to

FIGS. 48 and 49

.

FIG. 48

is an explanatory view showing a main part of the embodiment of the multistage compression apparatus of the present invention, and

FIG. 49

is an explanatory view showing a sectional structure of the first reciprocating compression section of the multistage compression apparatus of the present invention shown in FIG.


48


.




Additionally, in these drawings the components denoted by the same reference numerals as those of

FIGS. 50

,


51


have functions similar to those described in the related art, and the description thereof is omitted as long as the understanding of the present invention is not hindered.




As shown in

FIG. 48

, a multistage compression apparatus


1100


A of the present invention is similar to the multistage compression apparatus


1100


shown in

FIG. 51

, except that the gas compressed in the first reciprocating compression section


1101


provided with a double compression structure is fed to the next reciprocating compression section via a pipeline


1060


and is successively highly pressurized. Specifically, the four reciprocating compression sections


1101


,


1102


,


1103


,


1104


are arranged to reciprocate/cooperate on the axes


1105


,


1106


crossing at right angles to each other, the gas is successively highly pressurized from the first reciprocating compression section


1101


and fed to the next reciprocating compression section via the pipeline


1060


and the fourth reciprocating compression section


1104


is set as the high-pressure compression section of the final stage.





FIG. 49

is an explanatory view showing a sectional structure of the first reciprocating compression section


1101


of the multistage compression apparatus


1100


A of the present invention. The first reciprocating compression section


1101


is provided with a first compression chamber


1058


and a second compression chamber


1059


. When the piston


1051


advances to close the vales


10




a


,


10




b


, the gas is sucked into the first compression chamber


1058


via opened valves


10




e


,


10




f


from the directions shown by arrows and the gas in the second compression chamber


1059


is compressed to reach the predetermined pressure, and the gas is then discharged to the outside via the opened valves


10




c


,


10




d


and fed to the next reciprocating compression section as shown by arrows. Subsequently, when the piston


1051


moves backward to close the valves


10




e


,


10




f


, and the gas in the first compression chamber


1058


is compressed to reach the predetermined pressure and open the valves


10




a


,


10




b


and is discharged to the second compression chamber


1059


. Additionally, numeral


1060


denotes a rod guide for smoothly guiding the connecting rod


1057


to a determined position so that no vibration occurs.




In the present invention, a structure in which the gas is sucked, compressed and discharged in one cylinder


1055


in two stages in this manner is referred to as the double compression structure.




The nitrogen gas, the cylinders of the same size, and an actual apparatus were used to measure discharge amounts (m


3


/hr) in the first reciprocating compression section provided with the normal compression structure shown in FIG.


50


and in the first reciprocating compression section provided with the double compression structure shown in FIG.


49


.




As the test result, a discharge amount of 4.3 m


3


/hr was obtained in the compression section provided with the normal compression structure, and a discharge amount of 4.8 m


3


/hr was obtained in the compression section provided with the double compression structure. It has been found from the test result that when the compression section provided with the double compression structure is used, the discharge amount is 4.8/4.3=1.116 and can be increased by about 11.6%. A theoretical value is 12%, and substantially the same value as the theoretical value was obtained in the test.




Additionally, since the present invention is not limited to the aforementioned embodiment, various modifications are possible without departing from the scope defined in the appended claims.




For example, in the aforementioned embodiment, the first reciprocating compression section is provided with the double compression structure, but the second reciprocating compression section may also be provided with the double compression structure in the multistage compression apparatus.




Moreover, a plurality of reciprocating compression sections may be arranged in the L type, V type, W type, semi-star type, star type, opposite balance type, and the like as described above, or three or five or more reciprocating compression sections may be arranged in the star type in the multistage compression apparatus.




In the multistage compression apparatus of the present invention, for example, by providing the first reciprocating compression section with the double compression structure, the discharge amount can efficiently be increased without enlarging the diameter of the cylinder.



Claims
  • 1. A compression apparatus provided with compression means provided with a plurality of compression sections, driving means for driving the compression means, and a sealed case in which the driving means is disposed and whose top portion closely abuts on said compression means, wherein a relief valve, opened when a pressure in said sealed case is equal to or more than a predetermined pressure, is disposed in a bottom of the sealed case.
  • 2. A compression apparatus as claimed in claim 1 wherein said plurality of compression sections are provided with a compression mechanism for reciprocating/driving a piston with respect to a cylinder by rotation of a motor and compressing an operating fluid sucked by the driving to generate a high-pressure operating fluid, wherein said compression mechanism comprises a non-lubricating seal structure between an operation inner surface of said cylinder and said piston, and said piston is connected to a connecting rod by pressing a connecting flange portion extended to a rear end of said piston in a connection space formed in said connecting rod by a spring so that said piston can oscillate with respect to said connecting rod.
  • 3. A compression apparatus as claimed in claim 1 wherein there are a pair of said compression sections comprising at least one pair of opposite pistons, a yoke to which the pistons are fixed, and a cross slider for sliding and moving in the yoke, for obtaining a reciprocating motion of the piston from a rotation motion of a crank shaft through conversion by a scotch yoke mechanism, wherein a cover provided with an opening disposed in a middle portion not to inhibit a crank pin motion is fixed and disposed to sandwich the yoke.
  • 4. The compression apparatus according to claim 1 provided with a plurality of reciprocating compression sections, at least one of the plurality of reciprocating compression sections comprising a plunger pump, said plurality of reciprocating compression sections being connected to compress a required gas in multiple stages, wherein said plunger pump comprises a piston inserted into a ceramic cylinder liner, and a connecting rod connected to the piston, a sleeve is interposed as a pressure resistant structure member between said cylinder liner and a plunger pump main body, and said cylinder liner and the sleeve are fixed to the plunger pump main body via a fixing bolt.
  • 5. The compression apparatus according to claim 1, wherein a leaf spring or another elastic cushion member is interposed and attached between a connecting rod sleeve into which the connecting rod is inserted and said fixing bolt.
  • 6. The compression apparatus according to claim 1 provided with at least one pair of opposite pistons, a yoke to which the pistons are fixed, and a cross slider for sliding and moving in the yoke, for obtaining a reciprocating motion of the piston from a rotation motion of a crank shaft through conversion by a scotch yoke mechanism, wherein a cover provided with an opening disposed in a middle portion not to inhibit a crank pin motion is fixed and disposed to sandwich the yoke.
  • 7. The compression apparatus according to claim 6 wherein said cover is shrink-fitted and fixed to the yoke.
  • 8. A compression apparatus provided with a plurality of reciprocating compression sections, at least one of the plurality of reciprocating compression sections comprising a plunger pump, said plurality of reciprocating compression sections being connected to compress a required gas in multiple stages, wherein said plunger pump comprises a piston inserted into a ceramic cylinder liner, and a connecting rod connected to the piston, a sleeve is interposed as a pressure resistant structure member between said cylinder liner and a plunger pump main body, and said cylinder liner and the sleeve are fixed to the plunger pump main body via a fixing bolt, and an elastic cushion member interposed and attached between a connecting rod sleeve into which said connecting rod is inserted and said fixing bolt.
  • 9. A compression apparatus provided with a plurality of reciprocating compression sections, at least one of the plurality of reciprocating compression sections comprising a plunger pump, said plurality of reciprocating compression sections being connected to compress a required gas in multiple stages, wherein said plunger pump comprises a piston inserted into a ceramic cylinder liner, and a connecting rod connected to the piston, a sleeve is interposed as a pressure resistant structure member between said cylinder liner and a plunger pump main body, and said cylinder liner and said sleeve are fixed to the plunger pump main body via a fixing bolt and wherein one or two or more pressure release grooves are disposed through a thickness direction in a surface by which the sleeve as the pressure resistant structure member contacts the fixing bolt.
  • 10. The compression apparatus according to claim 9 wherein a leaf spring or another elastic cushion member is interposed and attached between a connecting rod sleeve into which the connecting rod is inserted and said fixing bolt.
  • 11. The compression apparatus according to claim 9 wherein one or two or more pressure release holes are disposed through the connecting rod sleeve.
  • 12. A compression apparatus provided with a plurality of reciprocating compression sections, at least one of the plurality of reciprocating compression sections comprising a plunger pump, said plurality of reciprocating compression sections being connected to compress a required gas in multiple stages, wherein said plunger pump comprises a piston inserted into a ceramic cylinder liner, and a connecting rod connected to the piston, a sleeve is interposed as a pressure resistant structure member between said cylinder liner and a plunger pump main body, and said cylinder liner and said sleeve are fixed to the plunger pump main body via a fixing bolt and wherein a width of either one or both of a piston ring groove and a guide ring groove, disposed in the piston, for attaching a piston ring and a guide ring is larger than the width of the ring itself.
  • 13. A compression apparatus provided with at least one pair of opposite pistons, a yoke to which the pistons are fixed, and a cross slider for sliding and moving in the yoke, for obtaining a reciprocating motion of the piston from a rotation motion of a crank shaft through conversion by a scotch yoke mechanism, wherein a cover provided with an opening disposed in a middle portion not to inhibit a crank pin motion is fixed and disposed to sandwich the yoke, wherein a position of at least one pair of opposite positions is provided with no piston, and said position is provided with a connecting rod fixed to the yoke, and a cylinder for guiding the connecting rod so that the connecting rod can reciprocate.
  • 14. The compression apparatus according to claim 13 wherein said cover is shrink-fitted and fixed to the yoke.
  • 15. A high pressure compression apparatus provided with a compression mechanism for reciprocating/driving a piston with respect to a cylinder by rotation of a motor and compressing an operating fluid sucked by the driving to generate a high-pressure operating fluid, wherein said compression mechanism comprises a non-lubricating seal structure between an operation inner surface of said cylinder and said piston, and said piston is connected to a connecting rod by pressing a connecting flange portion extended to a rear end of said piston in a connection space formed in said connecting rod by a spring so that said piston can oscillate with respect to said connecting rod, wherein one or two or more pressure release holes are disposed through the connecting rod sleeve.
  • 16. A high pressure compression provided with a compression mechanism for reciprocating/driving a piston with respect to a cylinder by rotation of a motor and compressing an operating fluid sucked by the driving to generate a high-pressure operating fluid, wherein said compression mechanism comprises a non-lubricating seal structure between an operation inner surface of said cylinder and said piston, and said piston is connected to a connecting rod by pressing a connecting flange portion extended to a rear end of said piston in a connection space formed in said connecting rod by a spring so that said piston can oscillate with respect to said connecting rod and wherein no piston is disposed in a position of at least a pair of opposite positions, and said position is provided with a connecting rod fixed to the yoke, and a cylinder for guiding the connecting rod so that the connecting rod can reciprocate.
  • 17. A high pressure compression apparatus provided with a plurality of reciprocating compression sections, at least one of the plurality of reciprocating compression sections comprising a plunger pump, said plurality of reciprocating compression sections being connected to compress a required gas in multiple stages, wherein said plunger pump comprises a piston inserted into a ceramic cylinder liner, and a connecting rod connected to the piston, a sleeve is interposed as a pressure resistant structure member between said cylinder liner and a plunger pump main body, and said cylinder liner and the sleeve are fixed to the plunger pump main body via a fixing bolt wherein a leaf spring or another elastic cushion member is interposed and attached between a connecting rod sleeve into which the connecting rod is inserted and said fixing bolt, and wherein one or two or more pressure release grooves are disposed through a thickness direction in a surface by which the sleeve as the pressure resistant structure member contacts the fixing bolt.
  • 18. A compression apparatus provided with at least one pair of opposite pistons, a yoke to which the pistons are fixed, and a cross slider for sliding and moving in the yoke, for obtaining a reciprocating motion of the piston from a rotation motion of a crank shaft through conversion by a scotch yoke mechanism, wherein a cover provided with an opening disposed in a middle portion not to inhibit a crank pin motion is fixed and disposed to sandwich the yoke wherein a position of at least one pair of opposite positions is provided with no piston, and said position is provided with a connecting rod fixed to the yoke, and a cylinder for guiding the connecting rod so that the connecting rod can reciprocate and wherein said cover is shrink-fitted and fixed to the yoke.
Priority Claims (1)
Number Date Country Kind
11-260439 Sep 1999 JP
Parent Case Info

This is a division, of application Ser. No. 09/662,206, filed Sep. 14, 2000, now U.S. Pat. No. 6,547,534 allowed Nov. 18, 2002. Each of these prior applications is hereby incorporated herein by reference, in its entirety.

US Referenced Citations (8)
Number Name Date Kind
4266443 McWhorter May 1981 A
4627795 Schmitz-Montz Dec 1986 A
4957416 Miller et al. Sep 1990 A
5033940 Baumann Jul 1991 A
5092185 Zornes et al. Mar 1992 A
5584675 Steurer et al. Dec 1996 A
5846059 Mizuno et al. Dec 1998 A
6293764 Baumann Sep 2001 B1
Foreign Referenced Citations (2)
Number Date Country
4-164174 Jun 1992 JP
11-280649 Oct 1999 JP