Gaseous fluid compression device

Information

  • Patent Grant
  • 11002272
  • Patent Number
    11,002,272
  • Date Filed
    Thursday, August 17, 2017
    7 years ago
  • Date Issued
    Tuesday, May 11, 2021
    3 years ago
  • Inventors
  • Original Assignees
  • Examiners
    • Tremarche; Connor J
    Agents
    • Shumaker, Loop & Kendrick, LLP
    • Miller; James D.
Abstract
An apparatus for compressing gas-phase fluid including a housing having a wall, a stator having a base plate and a helical wall extending from one side of the base plate, and an orbiter having a base plate and a helical wall extending therefrom. The base plates are disposed such that the wall of the stator and the wall of the orbiter engage with each other to define closed working chambers. The volumes and positions of the working chambers are changed in response to the motion of the orbiter. The apparatus includes a guide device having an opening formed in the base plate of the orbiter and a pin coupled to the housing. The pin engages the opening. A sliding element is disposed between the wall of the housing and the orbiter and coupled to the wall. The pin is pressed into an opening formed in the sliding element.
Description
CROSS-REFERENCE TO RELATED PATENT APPLICATIONS

This application is a United States nation phase patent application based on PCT/KR2017/008956 filed on Aug. 17, 2017, which claims the benefit of German Patent Application No. 10 2016 118525.6 filed on Sep. 29, 2016, the entire disclosures of which are hereby incorporated herein by reference.


TECHNICAL FIELD

The present disclosure relates to an apparatus for compressing a gas-phase fluid, particularly a refrigerant. The apparatus includes a housing having a wall, a non-motional stator having a base plate and a helical wall extending from a first side of the base plate, and a motional orbiter having a base plate and a helical wall extending from the base plate. The base plates are disposed such that the wall of the stator and the wall of the orbiter engage with each other to define closed working chambers. The volumes and positions of the working chambers are changed in response to the motion of the orbiter.


BACKGROUND ART

Compressors referred to as refrigerant compressors are used for movable applications to provide refrigerant through a refrigerant passage, particularly for air-conditioning systems for vehicles, which are well known in the art. These compressors are sometimes configured as piston compressors or scroll compressors that each have a variable stroke volume irrespectively of refrigerant. The compressors are driven by pulleys or in an electrical manner.



FIGS. 1 and 2 illustrate a scroll compressor 1′, which is well known in the art, in section. The conventional scroll compressor 1′ includes a housing 2, a non-motional fixed stator 3, which has a disk-type base plate 3a and a helical wall 3b extending from the base plate 3a, and a motional orbiter 4 which has a disk-type base plate 4a and a helical wall 4b extending from the base plate 4a. In brief, the stator 3 referred to as a non-motional or fixed spiral 3 cooperates with the orbiter 4 referred to as a motional spiral 4. The base plates 3 and 4 are disposed such that the wall 3b of the stator 3 engages with the wall 4b of the orbiter 4. The motional spiral 4 is moved in circular orbit by an eccentric actuator. The walls 3b and 4b come into contact with each other on multiple points during the motion of the spiral 4 to define a number of continuous closed working chambers 5 within the walls 3b and 4b, and adjacent working chambers 5 of them limit different large volumes. The volumes and positions of the working chambers 5 are changed in response to the motion of the orbiter 4. The volumes of the working chambers 5 are gradually reduced to the centers of the helical walls 3b and 4b referred to as spiral walls. The eccentric actuator consists of a drive shaft 6 rotating about an axis of rotation 7 and an intermediate element 8. The drive shaft 6 is supported on the housing 2 by a first bearing 9. The orbiter 4 is eccentrically connected with the drive shaft 6 by the intermediate element 8, namely the axes of the orbiter 4 and the drive shaft 6 are offset from each other. The orbiter 4 is supported on the intermediate element 8 by a second bearing 10.


The conventional scroll compressor 1′ also includes a guide device 11 that prevents the rotation of the motional spiral 4 and achieves the orbiting of the motional spiral 4. The guide device 11 generally includes a number of circular openings 11a arranged adjacently at a specific distance. Preferably, the openings 11a formed as blind holes are formed in the base plate 4a of the motional spiral 4. In addition, the guide device 11 includes pins 11b that are protrudingly formed on the wall 12 of the housing 2 and respectively engage into the openings 11a formed in the base plate 4a of the motional spiral 4. The first ends of the pins 11b protrude from the wall 12 and the second ends thereof are disposed within the wall 12 of the housing 2.


WO 2015 060038 A1 discloses a scroll compressor including a guide device to prevent the rotation of a motional spiral and achieve the orbiting thereof. The guide device includes openings formed in a base plate of the motional spiral and pins engage into the openings. The pins are pressed into a housing, particularly bores formed in the housing.


JP 2009-281280 discloses a scroll compressor with the cooling of a mechanism for adjusting the rotational position of a motional spiral. A component formed as a center plate of a housing includes through-bores for positioning guide pins for the motional spiral. Each of the guide pins is pressed into an associated one of the through-bores. The guide pins are cooled on the one hand by a refrigerant flowing between the center plate and the motional spiral and on the other hand by a refrigerant introduced into the through-bores from the side of center plate away from the motional spiral.


As illustrated in FIGS. 1 and 2, the known scroll compressor 1′ includes the wall 12 referred to as a facing wall 12 which is disposed in and fixed on the housing 2. A counter-pressure area 13 is defined between the facing wall 12 and the motional spiral 4. By the counter pressure occurring in the counter-pressure area 13, the motional spiral 4 applies force to the fixed spiral 3 fixed on the housing 2 such as the facing wall 12. To seal the counter-pressure area 13 and a suction area 14, a ring-shaped sealing element 15 is disposed between the motional spiral 4 and the facing wall 12. The motional spiral 4 has a surface 16 aligned toward the facing wall 2 on one end thereof. The sealing concept of the scroll compressor 1′ includes a sliding element 17′ formed as a plate together with the sealing element 15, and the sliding element is fixedly coupled to the housing, particularly the facing wall 12 without movement.


The plate-type fixed sliding element 17′ disposed between the facing wall 12 and the spiral 4 is provided as a support surface of the surface of the motional spiral 4 together with the sealing element 15, and for compensation of friction generated by the relative motion between the facing wall 12 and the spiral 4. The sliding element 17′ seals the suction area 14 and the counter-pressure area 13 from each other by a combination with the sealing element 15, the suction area 14 and the counter-pressure area 13 being pressure chambers to which two different pressures are applied. In addition, the sliding element 17′ has to abut on the facing wall 12 of the housing 2 in a sealed manner. The sealed coupling is ensured by adhesion and lubricants, particularly refrigerant oil mixtures. The sliding element 17′ is made of a material having very good tribological characteristics and has corrosion resistance and heat resistance. The scroll compressors 1′ known in the art include the sliding element 17′ disposed on the housing 2 with a very small wall thickness. The pins 11b, which are provided as guide elements and disposed within the facing wall 12, and the openings 11a, which are formed as pockets in the base plate 4a of the motional spiral 4, are circulated and thus provided to guide the spiral 4 in motion. In connection with the material of the housing 2, particularly the sealing and corrosion resistance thereof, the pins 11b must be made of aluminum. However, aluminum is not suitable in relation to tribological characteristics and strength.


In refrigerant passages through which carbon dioxide as a refrigerant with cooling technical sign R744 flows, the pressure level of suction pressure and discharge pressure occurring in the scroll compressor 1′ is substantially higher than in the conventional refrigerant passages, namely a pressure difference in refrigerant within the working chambers 5 is substantially higher than, for example, in the scroll compressor 1′ used in refrigerant passages through which R134a as a refrigerant flows. A higher pressure difference makes the force, which acts on the pins 11b from the orbiter 14, substantially larger. The pins 11b conventionally made of steel are position pins or guide pins and are separately pressed into the housing 2 made of aluminum, which have a significantly different expansion efficiency from the aluminum of the housing 2. Due to the substantially higher acting force, the significantly different expansion efficiencies between steel and aluminum, and the small strength of aluminum, the scroll compressor 1′ known in the art has a high risk of misaligning the pins 11b within the wall 12 of the housing 2.


Other challenges are given in connection with an installation space to be optimized, particularly in the arrangement and formation of the bearings 9 and 10 relating to the changed requirements for accommodation of substantially larger force into the area of the second bearing 10. The installation space is limited due to the relatively small strength of aluminum and the reason is because the fixed minimum material thickness or wall thickness of the housing 2 is required between recesses for insertion of the pins 11b and the bearing 10. In addition, the motional spiral 4 is designed to be heavier by demands for higher action force thereon, and the immediate element 8 having a larger counterweight provided as the weight for compensating the imbalance of orbiter 4 is also formed. The immediate element 8, particularly the counterweight is disposed in the recess into which the bearing 10 is inserted. The installation space for the immediate element 8 is very limited.


SUMMARY

An object of the present disclosure is therefore to provide an apparatus for compressing gas-phase fluid, particularly to improve a scroll compressor having a counter-pressure area and a suction area to which a fluid is applied at different pressure levels. The counter-pressure area can be sealed to the suction area in a sealed manner, and it is possible to compensate friction of an orbiter on a housing. Since position pins or guide pins of a guide device to prevent the rotation of the motional spiral and achieve the orbiting thereof are securely and continuously disposed, the maximum service life of the apparatus is ensured. The apparatus can be configured for the high pressure level of fluid. The apparatus must be easily implemented in its structure to minimize costs at the time of manufacture and maintenance.


This object is achieved by a subject having the features shown and described herein.


The object is achieved by an apparatus for compressing a gas-phase fluid, particularly a refrigerant according to the present disclosure. The apparatus includes a housing having a wall, a non-motional stator having a base plate and a helical wall extending from one side of the base plate, and a motional orbiter having a base plate and a helical wall extending from the base plate. The base plates are disposed such that the wall of the stator and the wall of the orbiter engage with each other to define closed working chambers. The volumes and positions of the working chambers are changed in response to the motion of the orbiter. The apparatus also includes a guide device having at least one opening formed in the base plate of the orbiter and at least one pin fixedly coupled to and protruding from the housing. The pin engages into the opening formed in the base plate of the orbiter.


According to the concept of the present disclosure, the apparatus includes a sliding element disposed between the wall of the housing and the orbiter and fixedly coupled to the wall. According to the present disclosure, the at least one pin is pressed into an opening formed in the sliding element.


The sliding element may have a circular ring disk shape that has an inner diameter, an outer diameter, a thickness, an outer jacket surface, and two circular ring surfaces.


According to an embodiment of the present disclosure, the sliding element and the at least one pin may be made of materials in which values of strength and thermal expansion efficiency as material characteristics are in the same range. The meaning that there is in the same range is that the material characteristics such as strength and thermal expansion have only a negligible small deviation under the operating conditions such as specific pressure and temperature. The sliding element may be made of steel.


In the embodiment of the present disclosure, the at least one pin may also be made of steel.


According to a first alternative embodiment of the present disclosure, the sliding element may be pressed into and coupled to the housing by force-fit. According to a second alternative embodiment of the present disclosure, the sliding element may be incorporated into and coupled to the housing by transition-fit. The housing may include a recess having a side and a base surface. One circular ring surface of the sliding element may abut on the base surface of the recess. The side of the recess may be fitted and coupled to an outer jacket surface of the sliding element.


According to another embodiment of the present disclosure, the sliding element may include a ring-shaped groove for accommodation of a sealing element formed as an O-ring. The ring-shaped groove may be formed on an outer jacket surface of the sliding element. The sliding element and the sealing element may be provide to seal the suction area and counter-pressure area, separated from each other by the wall of the housing, particularly of the apparatus configured as a scroll compressor.


According to the embodiment of the present disclosure, the at least one opening formed in the sliding element for accommodation of the pin may be formed as a through-bore.


The at least one pin of the guide device may be disposed in the through-bore such that an end of the pin formed away from an end of the guide device engaging into the opening engages into an opening formed in the wall of the housing, on which the sliding element abuts, through the sliding element.


According to an alternative embodiment of the present disclosure, the apparatus may include pin elements formed to dispose within openings formed in the sliding element and to protrude into openings formed in the wall of the housing.


The pins of the guide device disposed in the through-bores and engaging into the openings formed in the wall of the housing through the sliding element and the pin elements protruding into the opening formed in the wall of the housing may prevent the rotation of the sliding element relative to the wall of the housing.


In summary, the apparatus according to the present disclosure has the following various features:

    • the pins of the guide device can be optimally aligned, for example even for higher requirements for pressure and force acting during the use of carbon dioxide as a fluid to be compressed since the tilting of the pins is prevented;
    • the wall thickness between the inner diameter of the housing in the counter-pressure area and the openings for accommodation of the pins of the guide device within the facing wall can be minimized;
    • by providing a larger installation space within the counter-pressure area compared to the conventional scroll compressors, it is possible to dispose a larger bearing and a larger intermediate element, particularly a larger counterweight to support the orbiter on the intermediate element and thus the drive shaft; and
    • it is possible to ensure the maximum service life of the apparatus configured for the high pressure levels of fluid.


Other individual matters, features, and advantages of the embodiments of the present disclosure are proposed in the following description of the embodiments with reference to the related drawings. The drawings illustrate the compression mechanism of the scroll compressor including the stator and orbiter defining the working chambers by the helical walls engaging with each other, the counter-pressure area defined between the orbiter and the housing, and the guide device to prevent the rotation of the motional spiral and achieve the orbiting thereof in section, respectively.


An apparatus for compressing gas-phase fluid according to the present disclosure has the following effects:

    • pins of a guide device can be optimally aligned, for example even for higher requirements for pressure and force acting during the use of carbon dioxide as a fluid to be compressed since the tilting of the pins is prevented;
    • the wall thickness between the inner diameter of a housing in a counter-pressure area and openings for accommodation of the pins of the guide device within a facing wall can be minimized;
    • by providing a larger installation space within the counter-pressure area compared to the conventional scroll compressors, it is possible to dispose a larger bearing and a larger intermediate element, particularly a larger counterweight to support an orbiter on an intermediate element and thus a drive shaft; and
    • it is possible to ensure the maximum service life of the apparatus configured for the high pressure levels of fluid.





BRIEF DESCRIPTION OF DRAWINGS


FIGS. 1 and 2 are cross-sectional views of a conventional scroll compressor, respectively;



FIG. 3 is a cross-sectional view a scroll compressor having a plate-type sliding element for accommodation of pins of a guide device, which are pressed into and coupled to a housing by force-fit coupling;



FIG. 4 is a cross-sectional view a scroll compressor having a plate-type sliding element for accommodation of pins of a guide device, which are pressed into a housing by force-fit coupling or coupled to the housing by transition-fit coupling; and



FIGS. 5 and 6 are individual views of the sliding element of FIG. 4.





BEST MODE FOR INVENTION


FIG. 3 illustrates an apparatus for compressing gas-phase fluid 1a, particularly a scroll compressor having a compression mechanism disposed in a housing 2, which consists of a stator 3 and an orbiter 4, in section. Helical walls 3b and 4b, which are respectively disposed on base plates 3a and 4a and engage with each other, define working chambers 5.


Since the orbiter 4 is moved in circular orbit by an eccentric actuator, the helical wall 4b orbits about the stationary helical wall 3b. During the relative motion of the helical walls 3b and 4b, the walls 3b and 4b come into contact with each other many times and define a number of working chambers 5 becoming smaller. The working chambers 5 become smaller and compress a fluid by the relative motion of two intertwined helical walls 3b and 4b. A gas-phase fluid to be compressed, particularly a refrigerant is sucked to be compressed in the apparatus 1a and discharged through an outlet which is not illustrated.


A drive shaft 6 driving the orbiter 4 is supported and maintained on the housing 2 by a first bearing 9, particularly a ball bearing. The drive shaft 6 and the first bearing 9 rotate about an axis of rotation 7 of the drive shaft 6. The first bearing 9 is disposed around the drive shaft 6 and the areas of the outer surface and side thereof abut on a wall 12 of the housing 2. The drive shaft 6 is mechanically connected to the orbiter 4 with eccentricity by an intermediate element 8 and a second bearing 10. The wall 12 limits a counter-pressure area 13 defined between the orbiter 4 and the housing 2 and forms a separation wall between the counter-pressure area 13 and a suction area 14. The counter-pressure area 13 is defined on the rear of the base plate 4a of the motional spiral 4 with respect to the helical wall 4b and provided to apply the pressure of the motional spiral 4 to the fixed spiral 3. An intermediate pressure between suction pressure and discharge pressure of a gas-phase fluid is substantially applied to the counter-pressure area 13 referred to as a counter-pressure chamber.


To seal the counter-pressure area 13 and the suction area 14 from each other, a ring-shaped sealing element 15 is disposed between the facing wall 12 and the surface 16 of the motional spiral 4 aligned toward the facing wall 12. The sealing concept with the sealing element 15 includes a sliding element 17a formed as a plate, and the sliding element is disposed between the facing wall 12 and the spiral 4. The plate-type fixed sliding element 17a provides a contact surface to the surface of the motional spiral 4 together with the sealing element 15 and is provided for compensation of friction occurring during the relative motion between the facing wall 12 and the spiral 4. The suction area 14 and the counter-pressure area 13 are sealed from each other by the sliding element 17a and the sealing element 15. In addition, the sliding element 17a abuts on the facing wall 12 of the housing 2 in a sealed manner, and the sealed coupling is ensured by adhesion and lubricants, particularly refrigerant oil mixtures. To reduce frictional heat occurring during the motion of the helical walls 3b and 4b and during the motion of the helical wall 4b of the orbiter 4 relative to the facing wall 12, and to improve sealing between the limited surfaces of the waking chambers 5 and between the counter-pressure area 13 and the suction area 14, a lubricant is provided for a fluid.


The apparatus 1a includes a guide device 11 to prevent the rotation of the motional spiral 4 and achieve the orbiting thereof. The guide device 11 includes a number of circular openings 11a and pins 11b formed in a direction of the counter-pressure area 13 in the base plate 4a of the orbiter 4. The first ends of the pins 11b protrude into the openings 11a and the second ends thereof are coupled to the housing 2. The pins 11b formed as position elements and guide elements and the openings 11a formed as recesses in the base plate 4a of the motional spiral 4 are provided to guide the motional spiral 4.


The sliding element 17a made of a corrosion-resistant and heat-resistant material having very good tribological characteristics such as steel is coupled to the housing 2, particularly the facing wall 12 without being fixed and moved thereto.


The pins 11b made of steel as well are arranged in the openings, particularly through-bores formed in the sliding element 17a, respectively. The pins 11b are pressed into the openings by the sliding element 17a. Since each of the pins 11b and the sliding element 17a which are made of steel have a very high strength and a similar thermal expansion efficiency, different thermal expansions between the pins 11b and the sliding element 17a are prevented. This prevents the wall 12 of the housing 2 and thus the pins 11b to the openings 11a of the motional spiral 4 from tilting during the operation of the apparatus 1a. The pins 11b are continuously disposed in position and in parallel to each other, thereby ensuring an optimal guide condition for the motional spiral 4.


The sliding element 17a is coupled to the housing 2 by external force-fit. The sliding element 17a formed as a plate-type or circular ring disk is pressed into the housing 2 in the area of an outer jacket, which ensures the optimal guide of the sliding element 17a in the housing. The housing 2 includes a recess having a side and a base surface in the area of the facing wall 12. In an assembled state, one circular ring surface of the sliding element 17a abuts on the base surface of the recess of the housing 2, and the side of the recess is coupled to the outer jacket surface of the sliding element 17a by force-fit. In addition to or instead of the external force-fit, the sliding element 17a is supported in the housing 2 by at least one pin element which is not illustrated, and the pin element prevents the sliding element 17a from rotating relative to the housing 2. Preferably, one or two pin elements referred to as rotation prevention pins are used.


In particular, as illustrated in FIG. 3, the pins 11b of the guide device 11 are arranged to achieve the function of the rotation prevention pins. The pins 11b are arranged to protrude into the facing wall 12 through the sliding element 17a abutting on the facing wall 12. The openings provided to accommodate the pins 11b in the sliding element 17a are formed as through-openings. To accommodate the pins 11b, preferably openings or recesses are formed in the facing wall 12. In the case where the pins 11b are disposed to pass through the openings formed in the wall 12 through the sliding element 17a, the sliding element 17a is fixed on the housing 2.


By forming the sliding element 17a as a circular ring disk made of steel with a large inner diameter, the inner diameter of the circular ring disk becomes large by the high strength of material. Thus, the inner diameter of the substantially hollow cylindrical-type area of the housing 2, which is limited by the facing wall 12 and provided to accommodate the bearings 9 and 10 of the intermediate element 8, also becomes large. Therefore, the counter-pressure area 13 has a large inner diameter. The large inner diameter of the housing 2 and the large inner diameter of the sliding element 17a in the area of the counter-pressure chamber 13 create a large installation space for the bearings 9 and 10, particularly the second bearing 10 to support the orbiter on the intermediate element 8. The wall thickness between the pin bore in the sliding element 17a and in some cases the facing wall 12 and the bore for the bearing 10 is minimized by the very high strength of steel which is a material of the sliding element 17a and the pins 11b. The installation space for the bearing 10 is increased. The expansion of the installation space in the counter-pressure area 13 allows the volume of the intermediate element 8 to be large and thus ensures the use of a heavier counterweight.



FIG. 4 illustrates an apparatus for compressing gas-phase fluid 1b, particularly a scroll compressor having a plate-type sliding element 17b to accommodate the pins 11b of the guide device 11. The difference from the apparatus 1a illustrated in FIG. 3 is in that the sliding element 17b includes a groove 18, particularly a ring-shaped groove 18 for accommodation of an O-ring. The groove 18 and the O-ring as a sealing element disposed in the groove extend on the outer jacket surface of the circular ring disk and seal the sliding element 17b to the facing wall 12 and thus the housing 2.


Alternatively, the sliding element 17b is coupled to the housing 2 by external force-fit or transition-fit. The sliding element 17b formed as a circular ring disk is pressed into and put in the housing 2 in the area of the outer jacket. In addition to the individual fit coupling, the sliding element 17b may be disposed to be supported in the housing 2 by at least one pin element 19 that prevents the rotation of the sliding element 17b relative to the housing 2. Preferably, one or two pin elements 19 referred to as rotation prevention pins are used. The pin elements 19 are disposed within the openings formed in the sliding element 17b and protrude into the openings formed in the housing wall 12.


In the apparatus 1b including the ring-shaped groove 18 and the sliding element 17b having the O-ring, several and repetitive assembly and disassembly are possible, unlike the apparatus 1a, illustrated in FIG. 3, including the sliding element 17a disposed by force-fit coupling. The sealing of the counter-pressure area to the suction area 14 is always recoverable.


In addition, the apparatus 1b may be provided with an intermediate element 8 that has a larger volume and thus has a heavier counterweight. It is possible to more flexibly use the provided installation space because the intermediate element 8, particularly the counterweight may have an undercut shape.



FIGS. 5 and 6 are individual views illustrating the sliding element 17b of the apparatus 1b illustrated in FIG. 4. The circular ring disk type sliding element 17b has an inner diameter d, an outer diameter D, and a thickness b. The thickness b ranges from 4 mm to 8 mm, particularly is made of about 6 mm. The inner diameter ranges from 50 mm to 55 mm, particularly is made of about 53 mm. The outer diameter ranges from 90 mm to 100 mm, particularly is made of about 96 mm.


The pins 11b are guided or inserted into the sliding element 17b within the openings formed in the area of the inner diameter d, and the openings are uniformly distributed and arranged at the same distance. In contrast, the pin elements 19 are rotation prevention pins, which are inserted into the sliding element 17b within the openings formed in the area of the outer diameter D.


The present disclosure relates to an apparatus for compressing a gas-phase fluid, particularly a refrigerant. The apparatus includes a housing having a wall, a non-motional stator having a base plate and a helical wall extending from a first side of the base plate, and a motional orbiter having a base plate and a helical wall extending from the base plate. The base plates are disposed such that the wall of the stator and the wall of the orbiter engage with each other to define closed working chambers. The volumes and positions of the working chambers are changed in response to the motion of the orbiter.

Claims
  • 1. An apparatus for compressing gas-phase fluid comprising: a housing having a wall; a non-motional stator having a base plate and a helical wall extending from one side of the base plate; a motional orbiter having a base plate and a helical wall extending from the base plate, the base plate of the stator and the base plate of the motional orbiter disposed wherein the wall of the stator and the wall of the motional orbiter engage each other to define closed working chambers, volumes and positions of the working chambers being changed in response to motion of the motional orbiter; a counter-pressure area defined between the wall of the housing and the motional orbiter; a guide device having an opening formed in the base plate of the motional orbiter and a pin fixedly coupled to and protruding from the housing, the pin engaging into the opening; and a sliding element disposed between the wall of the housing and the motional orbiter and fixedly coupled to the wall of the housing, wherein the sliding element is provided for compensation of friction generated by relative motion between the wall of the housing and the motional orbiter, wherein the pin is pressed into an opening formed in the sliding element, wherein the sliding element is pressed into and coupled to the housing by a force-fit, wherein the housing comprises a recess having a side and a base surface, the side of the recess is fitted and coupled to an outer jacket surface of the sliding element so that a first circular ring surface of the sliding element is fixed in contact with the base surface of the recess.
  • 2. The apparatus according to claim 1, wherein the sliding element has a circular ring disk shape that has an inner diameter, an outer diameter, a thickness, the outer jacket surface, the first circular ring surface, and a second circular ring surface.
  • 3. The apparatus according to claim 1, wherein the sliding element and the pin are made of materials in which values of strength and thermal expansion efficiency as material characteristics are similar.
  • 4. The apparatus according to claim 1, wherein the sliding element is made of steel.
  • 5. The apparatus according to claim 1, wherein the pin is made of steel.
  • 6. The apparatus according to claim 1, wherein the sliding element comprises a ring-shaped groove for accommodation of a sealing element formed as an O-ring.
  • 7. The apparatus according to claim 6, wherein the ring-shaped groove is formed on the outer jacket surface of the sliding element.
  • 8. The apparatus according to claim 1, wherein the opening formed in the sliding element for accommodation of the pin is formed as a through-bore.
  • 9. The apparatus according to claim 8, wherein the pin of the guide device is disposed in the through-bore wherein an end of the pin formed away from an end of the guide device engaging into the opening engages into an opening formed in the wall of the housing through the sliding element.
  • 10. The apparatus according to claim 1, wherein the apparatus further comprises pin elements formed to dispose within openings formed in the sliding element and to protrude into openings formed in the wall of the housing.
Priority Claims (1)
Number Date Country Kind
102016118525.6 Sep 2016 DE national
PCT Information
Filing Document Filing Date Country Kind
PCT/KR2017/008956 8/17/2017 WO 00
Publishing Document Publishing Date Country Kind
WO2018/062684 4/5/2018 WO A
US Referenced Citations (5)
Number Name Date Kind
4702683 Inaba Oct 1987 A
20150152731 Yamashita Jun 2015 A1
20160090986 Imai Mar 2016 A1
20160160646 Taguchi Jun 2016 A1
20160369799 Duppert Dec 2016 A1
Foreign Referenced Citations (23)
Number Date Country
60300376 Feb 2006 DE
1464840 Oct 2004 EP
1867876 Dec 2007 EP
2012016 Jan 2009 EP
2218914 Aug 2010 EP
2618000 Jul 2013 EP
H02277988 Nov 1990 JP
H0668276 Aug 1994 JP
H08338376 Dec 1996 JP
H09151864 Jun 1997 JP
2001132670 May 2001 JP
2004124735 Apr 2004 JP
2009281280 Dec 2009 JP
2012167605 Sep 2012 JP
2012229650 Nov 2012 JP
2015034506 Feb 2015 JP
2015086765 May 2015 JP
2016156297 Sep 2016 JP
100446213 Aug 2004 KR
20140095827 Aug 2014 KR
2015016028 Feb 2015 WO
2015060038 Apr 2015 WO
2015198516 Dec 2015 WO
Non-Patent Literature Citations (1)
Entry
“Groover, Mikell P., Fundamentals of Modern Manufacturing: Materials, Processes, and Systems, 2007, John Wiley and Sons, 3rd Edition, p. 772” (Year: 2007).
Related Publications (1)
Number Date Country
20190285066 A1 Sep 2019 US