EP1869323B1 - Refrigerant compressor - Google Patents
Refrigerant compressor Download PDFInfo
- Publication number
- EP1869323B1 EP1869323B1 EP06725444A EP06725444A EP1869323B1 EP 1869323 B1 EP1869323 B1 EP 1869323B1 EP 06725444 A EP06725444 A EP 06725444A EP 06725444 A EP06725444 A EP 06725444A EP 1869323 B1 EP1869323 B1 EP 1869323B1
- Authority
- EP
- European Patent Office
- Prior art keywords
- pressure
- valve plate
- suction
- refrigerant compressor
- channel
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04B—POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS
- F04B39/00—Component parts, details, or accessories, of pumps or pumping systems specially adapted for elastic fluids, not otherwise provided for in, or of interest apart from, groups F04B25/00 - F04B37/00
- F04B39/12—Casings; Cylinders; Cylinder heads; Fluid connections
- F04B39/123—Fluid connections
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04B—POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS
- F04B39/00—Component parts, details, or accessories, of pumps or pumping systems specially adapted for elastic fluids, not otherwise provided for in, or of interest apart from, groups F04B25/00 - F04B37/00
- F04B39/06—Cooling; Heating; Prevention of freezing
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F04—POSITIVE - DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS FOR LIQUIDS OR ELASTIC FLUIDS
- F04B—POSITIVE-DISPLACEMENT MACHINES FOR LIQUIDS; PUMPS
- F04B39/00—Component parts, details, or accessories, of pumps or pumping systems specially adapted for elastic fluids, not otherwise provided for in, or of interest apart from, groups F04B25/00 - F04B37/00
- F04B39/12—Casings; Cylinders; Cylinder heads; Fluid connections
- F04B39/125—Cylinder heads
Definitions
- the present invention relates to a hermetically sealed refrigerant compressor with a hermetically sealed compressor housing, in the interior of which a refrigerant-compressing piston-cylinder unit operates, whose cylinder housing is closed by means of a pressure bore and a suction bore having valve plate and a suction channel and a pressure channel are provided via which refrigerant is sucked via a suction valve in the suction hole and compressed via a pressure valve from the pressure bore into the pressure channel, wherein the suction channel is formed by a channel-shaped component which is sealed along a Saug.kante with the valve plate and the suction hole provided with a preferred Suction muffler connects, according to the preamble of claim 1 or 2.
- Such refrigerant compressors have long been known and are mainly used in refrigerators or shelves. Accordingly high is the annually produced quantity.
- the refrigerant process as such has long been known.
- the boiling refrigerant is vaporized by energy absorption from the space to be cooled in the evaporator and finally superheated and pumped by the refrigerant compressor to a higher energy level, where it emits heat through a condenser and via a throttle, in which a pressure reduction and the cooling of the refrigerant , is transported back to the evaporator.
- hermetic refrigerant compressors In known hermetic refrigerant compressors according to the prior art is due to design a strong heating of the refrigerant on its way from the evaporator (refrigerator) to the intake valve of the piston-cylinder unit.
- the suction channel usually opens directly into the interior of the hermetically sealed compressor housing in the vicinity of the inlet opening in a suction muffler, which reduces the intake noise of the piston-cylinder unit and is usually constructed of a plurality of interconnected volumes, as well as having the aforementioned inlet opening and an outlet opening which bears tightly against the suction bore of the valve plate.
- Any known refrigerant compressor in any case have an identical structure of the piston-cylinder unit, in particular of the cylinder housing, which is closed with a valve plate and an adjoining cylinder cover.
- the cylinder cover preferably covers the entire valve plate, which also has the suction bore and the pressure bore.
- On the valve plate and the suction hole temporarily closing suction valve and the pressure bore temporarily occluding pressure valve are arranged.
- the cylinder cover is usually provided with a recess for the suction channel, or for the end portion of the suction muffler, which opens into the suction hole.
- the heated by the compression process refrigerant is forced through the pressure valve and the pressure bore from the cylinder in the cylinder cover, where it completely fills at least in the pressure channel forming portion due to the construction of the cylinder cover and thus with the part of this pressure channel forming valve plate in Touch comes.
- the temperature of the valve plate corresponds due to this fact substantially the temperature of the compressed refrigerant. Since the gas in the interior of the cylinder over more than 300 ° crank angle is colder than the valve plate, there is a heat flow from directly the valve plate or indirectly from the valve plate to the cylinder wall and from there to the gas inside the cylinder, which adversely affects the Energy efficiency.
- the high temperature prevailing in the cylinder cover also causes a heat flow in the direction of the end section of the suction muffler, which is indeed surrounded by the cylinder cover, whereby, however, the refrigerant coming from the suction muffler, which is still to be compressed, is also undesirably heated.
- the known refrigerant compressor designs due to their cylinder cover construction of the initially mentioned objective, namely a reduction of the suction temperature and the Ausschiebetemperatur, run counter.
- claims 1 or 2 describe a preferred embodiment of the tight connection of the suction or pressure channel forming components to the valve plate in order to prevent leakage of the refrigerant from the channels into the interior of the compressor housing can guaranteed.
- the formation of the sealing bead in conjunction with the sealing projections requires a much lower required pressing force between pressure or suction port and valve plate than is the case between cylinder cover and valve plate in known cylinder heads.
- the known embodiments described above also have the disadvantage that the refrigerant heats up too much on its way from the inlet to the interior of the compressor housing to the suction bore. Measurements have shown that between a point in the suction channel shortly before entering the compressor housing and the first volume of the suction muffler, a heating by more than 20 ° C takes place. The main cause of this undesirable Heating of the refrigerant is the fact that the fresh refrigerant flowing from the suction channel into the compressor housing is mixed with refrigerant already in the compressor housing.
- an independent component is provided which forms the pressure channel and this completely sheathed. By directly connecting this component with the pressure bore, a complete thermal separation of the pressure channel from the valve plate takes place.
- These components allow the direct, hot refrigerant to escape directly through the pressure hole in the Pressure channel, without having to flow along a portion of the valve plate. Only the region of the valve plate which directly surrounds the pressure bore comes into contact with the hot refrigerant at its side facing away from the piston. As a result, the heat transfer from the hot, already compressed refrigerant to the valve plate over conventional cylinder heads in refrigerant compressors can be drastically reduced.
- valve plate and the cylinder wall remain cooler and thereby allow a dissipation of heat from the interior of the cylinder housing, or prevent the inflow of heat into the gas in the cylinder. Furthermore, in this way, the heat transfer from the valve plate to the suction hole and thus into the suction channel can be reduced, whereby the intake temperature can be lowered.
- portion of the pressure channel which impinges on the valve plate that is, that portion which lies within the pressure contact edge, can be accurately dimensioned and optimized with respect to heat transfer. It is necessary on the one hand, that the pressure bore is within this range and on the other hand, the transition between the pressure channel and the pressure bore is formed aerodynamically and still allows a tight connection. Since according to the invention, the pressure channel or more precisely the last portion of these channels substantially perpendicular to the pressure bore and thus impinges on the valve plate to prevent heat transfer from the valve plate to the pressure channel or vice versa, the shape of the pressure contact edge can be chosen so that the refrigerant flows around the valve plate only along a small area.
- the ratio of the cross-sectional area of the pressure bore to the through Pressure contact edge enclosed area is more than 1/12.
- the component forming the pressure channel has a directly leading to the pressure bore, leading away from the valve plate portion and a subsequent section to this section further, relative to the cylinder bore radially outwardly, preferably at a distance from the valve plate preferably runs parallel thereto.
- the portion leading away from the valve plate and / or the further portion of the pressure channel is made of poorly conductive plastic, whereby the heat output of the compressed refrigerant can be further reduced.
- an insulating material preferably made of rubber or plastic, to further reduce the heat transfer from the compressed refrigerant to the valve plate.
- the component comprising the two channels for example, can be produced by injection molding from plastic, whereby the heat transfer from the pressure channel into the interior of the compressor housing, from the interior of the compressor housing into the suction channel and in the region of the suction or pressure contact edge in the valve plate can be further reduced.
- the characterizing features of claim 10 provide that the pressure bore occluding pressure valve is arranged in the pressure channel forming member. This allows the valve plate easier, ie. be manufactured in fewer steps, since the provision of a fastening for the pressure valve in the valve plate is no longer required. At the same time, the realization of this feature enables a pre-assembling of pressure channel and pressure valve or together with the features of claim 10, a pre-assembling of pressure channel and pressure valve, including suction channel.
- the clamping element is latched according to the characterizing features of claim 16 with an end portion provided on the cylinder housing undercuts.
- the cylinder housing may be further provided with a step in which the valve plate is at least partially recessed to allow positioning thereof, since positioning, as known by screwing in conventional cylinder heads of refrigerant compressors, due to the clamping is no longer possible , wherein a preferred embodiment provides that those facing away from the piston surface of the valve plate is flush with the cylinder housing.
- the fastening of the components forming the suction or pressure channel takes place on the valve plate by means of further clamping legs arranged on the clamping element.
- a separate further clamping element is provided, which clamps the suction or pressure channel forming components to the valve plate, said separate clamping element can be latched to the clamping element.
- valve plate by means of separate fasteners, such as screws on Cylinder housing is fixed, but the pressure or suction duct forming components are clamped to the valve plate, thus a combination of clamping and screwing.
- Fig.1 shows an axonometric view of a cylinder head, wherein portions of the cylinder housing 1, the valve plate 2, and the suction muffler 3, together with intake 3a are visible.
- the basic structure of the subject hermetically sealed refrigerant compressor is known per se.
- the piston-cylinder-motor unit consists essentially of a cylinder housing 1 and the therein a stroke advancing piston 4, and a crankshaft bearing 5 in a crankcase 5a, which is arranged perpendicular to the cylinder axis 6.
- the crankshaft bearing 5 receives a crankshaft (not shown) and protrudes into a central bore of the rotor Electric motor (also not drawn).
- a suction muffler 3 is arranged to reduce the noise during the intake of the refrigerant to a minimum.
- Fig.1 and Fig.2 show an embodiment of a cylinder head in a fully assembled state, ie. with a clamping element 7, whereas Figure 3 However, the same cylinder head without clamping element 7 shows.
- Both components 8,9 are independent of each other and in particular also independent of the valve plate 2, with which, however, along a contact edge, namely a pressure contact edge 13 and a Suction contact edge 17, which will be discussed in more detail later, are tightly connected.
- limit the components 8.9 which can also be referred to with pressure channel 8 and suction channel 9, each a completely self-sufficient channel, they completely encase until it hits the valve plate.
- the component 8 forming the pressure channel has a section 8a leading directly to the pressure bore 10 away from the valve plate 2 and a further section 8b adjoining this section 8a, which is essentially radially outward relative to the cylinder bore, preferably at a distance Z to the valve plate 2 is preferably parallel thereto (see also Figure 10 and 11 ).
- the distance Z between the component 8 and the valve plate 2 causes optimum isolation of the valve plate 2 from the pressure channel, so that a heat transfer from the compressed, hot refrigerant in the pressure channel 8 on the valve plate 2 and on the suction channel 9 is strongly prevented.
- the component 8 forms a pressure chamber, which is arranged in the leading away from the valve plate 2 section 8a of the pressure channel 8 and a defined minimum volume does not fall below depending on the cooling capacity.
- This pressure chamber which is also referred to in the following with 8a, serves to avoid possible pressure surges when expelling the refrigerant from the cylinder.
- the pressure channel 8 is then transferred to the further section 8b, which leads the refrigerant out of the compressor housing.
- clamping element 7 is substantially Y-shaped and arched away from the piston 4 and is used exclusively for clamping the components 8,9 against the valve plate 2.
- the clamping element 7 itself is secured by screws 11 to the valve plate 2. The screws 11 are also used to attach the valve plate 2 to the cylinder housing. 1
- Figure 4 shows the previously described cylinder head with partially cut clamping element 7 and partially cut valve plate 2.
- the clamping element 7 presses with its one clamping portion 7a on a portion of the pressure channel forming member 8, whereby this against the valve plate 2 or more precisely via the pressure contact edge 13 at the valve plate is pressed.
- Figure 5 shows a view of the cylinder head in the direction of the crankshaft axis.
- the structure of the cylinder head according to the invention can be seen very well, in particular the clamping element 7, the valve plate 2 and the Cylinder housing 1, all three are connected to each other via the screws 11.
- Figure 6 shows a section along the line AA Fig.2 ,
- the component 8 according to the invention can be seen very well, which forms the pressure channel and this completely encased.
- the clamping element 7, which clamps the component 8 with its end portion 8c in the form of the pressure contact edge 13 against the valve plate 2 with its portion 7a.
- the distance Z can be seen very well, which is formed between the further portion 8b of the component 8 and the valve plate 2 and a heat transfer from the compressed, hot refrigerant-containing pressure channel 8 on the valve plate 2 and thus further into the cylinder interior 12th or in the suction channel 9, which is not visible in this sectional view, prevented.
- the compressed refrigerant in the first section 8a of the pressure channel 8 is led away from the valve plate and then led away at a distance Z in the radial direction with respect to the cylinder bore from the cylinder housing 1 without the compressed refrigerant having further contact with the valve plate 2 ,
- Figure 7 shows how Figure 5 a view of the cylinder head in the direction of the crankshaft axis, but without clamping element 7, so that the pressure channel forming member 8 is very well visible, as well as the distance Z between the component 8 and the valve plate. 2
- Fig.8 and Fig. 8a Both show that end portion of the portion 8a of the pressure channel forming member 8, which is sealed to the valve plate 2, which is not apparent in these figures, via the pressure contact edge 13. This, adjacent to the valve plate 2 and thus connected end portion forms according to the invention Pressure chamber 8a to prevent pressure increases when pushing the refrigerant out of the cylinder.
- the section 8a is further provided with receiving devices 19 in the form of pins, in which an end portion of a pressure valve 15 is suspended.
- the pressure valve 15 is formed in a conventional manner as a leaf spring element.
- That end section which can be suspended in the receiving devices serves as a fixed attachment section, whereas the free end section 15a opposite this end section alternately releases or closes the pressure bore 10 located immediately behind it in the valve plate 2 as a function of the compression cycle.
- the component 8 according to the invention is further provided with an opening limitation 26 in the form of a stop, as is apparent from Figure 8a is apparent. This opening limitation serves to limit the opening travel of the pressure valve 15.
- the inventive arrangement of the pressure valve 15 in the component 8 allows the prefabrication of these two parts along a separate production line.
- Component 8 together with pressure valve 15 and opening limit 26 can then be easily and quickly connected by means of clamping element 7 with the valve plate 2.
- the conventional way of attaching the pressure valve 15 to the valve plate 2, for example by riveting is then no longer necessary, resulting in a significant simplification and, above all, acceleration of the manufacturing process.
- Figure 9 shows an alternative embodiment of a cylinder head, in which in addition to the pressure and suction passage forming components 8,9 and the valve plate 2 is fixed via a clamping element 7 with the clamping portions 7a and 7b on the cylinder housing 1.
- Figure 10 shows a sectional view of the alternative embodiment Figure 9 , wherein the heat transfer between the pressure channel 8 and valve plate 2 and between the suction channel 9 and valve plate 2 inhibiting distance Z is very clearly visible.
- the clamping element 7 consists in this case of a clamping portion 7b, which surrounds the valve plate 2 in its edge region over the entire circumference and snaps into this embodiment at an undercut 27 on the cylinder housing 1, as in the detail view in fig.11 is clearly visible.
- Clearly visible in fig.11 is also the dead space seal 14, which is arranged between the valve plate 2 and the cylinder housing 1, and the suction valve 32nd
- the clamping element 7 has an additional clamping portion 7a, which is formed substantially U-shaped and the components 8,9 clamped against the valve plate 2.
- Figure 12 shows a section along the plane A from Figure 9 , In this view, the integrality of the clamping element 7 with the clamping portions 7a and 7b can be seen very clearly.
- the transition of the pressure channel forming member 8 is shown in the pressure bore 10.
- the component 8 according to the invention is tightly connected to the valve plate 2 along the pressure contact edge 13. Within the enclosed by the pressure contact edge 13 surface is the pressure bore 10, and the movable part of the pressure valve 15. The area enclosed by the pressure contact edge 13 surface is also the only portion of the valve plate 2, which comes into contact with the compressed refrigerant from the cylinder.
- suction contact edge 17 along which the suction channel 9 is connected tightly to the valve plate 2.
- Suction hole 16 Within the enclosed by the suction contact edge 17 surface is the Suction hole 16.
- the area enclosed by the suction contact edge 17 is at the same time the only portion of the valve plate 2 which comes into contact with the refrigerant drawn into the cylinder.
- the cylinder housing 1 has a shoulder 27, in which the valve plate 2 is at least partially, but preferably completely sunk, whereby at the same time a positioning of the valve plate 2 is achieved.
- FIG. 13 and FIG. 14 both show a further alternative embodiment of a cylinder head.
- the clamping element 7 is executed divided in the region of its clamping portion 7a, so that each component 8.9 has a clamping element 7 assigned to it.
- Fig.15 and Fig.16 Both show an additional embodiment variant of a cylinder head with an alternatively formed clamping element 7.
- the clamping portion 7b of the clamping element 7 surrounds the valve plate 2 in the edge region not over the entire circumference but is executed interrupted, the interruptions form openings in this clamping section in this case which the components are 8.9 away from the cylinder head and out to the cylinder head, so that actually several clamping portions 7b are present.
- the individual clamping portions 7b snap in the same manner as already described in the above-mentioned embodiments at an undercut 27 on the cylinder housing 1 a.
- the clamping portion 7a is formed cross-shaped in this embodiment, each one arm of this cross merges into a clamping portion 7b. That area in which the individual arms of the cross meet is cylindrical and causes the clamping of the components 8, 9.
- Fig.17 and Fig.18 show another alternative embodiment of a cylinder head, in which the clamping element 7, both the components 8,9 and the valve plate 2 clamped against the cylinder housing 1.
- the cylinder housing 1 is formed laterally raised, wherein the raised portion 1a has an undercut, in which the clamping element 7 with its clamping portion 7b can be latched.
- the valve plate 2, which terminates the cylinder housing 1 at the end and is axially surmounted by its portions 1a, is clamped in this case by the clamping portions 7b, which are latched to the undercut of the portion 1a, against the cylinder housing 1.
- the clamping portion 7a which in turn integrally forms with the clamping portion 7b, the clamping element 7, clamps the components 8,9 against the valve plate 2.
- the raised portion 1a is provided with openings 18 through which the components 8,9 away from the cylinder head or to Cylinder head are led out.
- the Fig.19 and 20 each show a sectional view of cylinder heads, in which on the one hand an O-ring seal 20 and on the other hand, a paper seal 21 for sealing the connection of the suction channel 9 and also the pressure channel 8 with the valve plate 2 are used.
- This type of seal is already known from the prior art, but there is the sealing of the connection of the valve plate with the cylinder cover, which is no longer required in a cylinder head.
- Figure 21 shows an alternative embodiment of a possible sealing of the connection of the pressure channel 8 and the suction channel 9 with the valve plate 2 based on an additional, further embodiment of a cylinder head according to the invention.
- the valve plate 2 to be provided with a sealing bead 23, in which a the outline of the sealing bead 23 on the valve plate 2 in Substantially corresponding, arranged at the DruckCountante 13 of the pressure channel forming member 8 and at the Saug.kante 17 of the suction channel forming member 9 arranged sealing extension 22 (see also 8 and 8a ) intervenes.
- a reverse embodiment is conceivable, ie. at the pressure contact edge 13 of the pressure channel forming member 8 and at the Saugumblekante 17 of the suction channel forming member 9 (see also 8 and 8a ), a sealing bead 23 is provided, in which a corresponding to the contour of the sealing bead 23, arranged on the valve plate 2 sealing projection 22 engages.
- the sealing extension 22 In order to ensure a sealing of the connection, the sealing extension 22 must either have a larger volume than the sealing bead 23 or the shape of the sealing extension 22 is different from that of the sealing bead 23.
- the applied during assembly of the cylinder head pressing forces, in particular the clamping forces of the clamping element 7 then cause the flow of the sealing extension 22 in the sealing bead 23 or of parts of the sealing extension 22 due to the high local surface pressure.
- sealing bead 23 in conjunction with the sealing projections 22 requires for the same tightness a much lower required pressing force between the pressure or suction passage 8.9 and valve plate 2 than is the case between cylinder cover and valve plate 2 in known cylinder heads.
- required surface pressure is the same in both systems, however, the sealing surfaces differ substantially, namely a long wide seal in the case of the paper seal and a short narrow sealing surface in the case of the sealing bead 23 - sealing system 22 system.
- the sealing system works independently of the material pairings used. So conventional material pairings are possible, such as metal (valve plate 2) - metal (components 8,9) or metal (valve plate 2) - flowable plastic (components 8,9) or plastic (valve plate 2) - flowable plastic (components 8 , 9).
- the surface pressure required for the present application can be given as 5 to 20 N / mm 2 .
- a particularly preferred geometric shape of the sealing bead 23 is the V-shape or U-shape according to FIGS Fig.24 to 31 , those of the sealing extension 23, the pin shape, wherein the free end of the sealing extension is preferably flattened or rounded.
- Figure 24 shows a simple embodiment of the sealing system with V-shaped sealing bead 23 and pin-shaped sealing extension 22nd
- Figure 25 shows a sealing bead 23 formed by two projecting from the valve plate 2 ribs, which cooperates with a pin-shaped sealing extension 22.
- the peg-shaped sealing extension 22 is flattened at its free end.
- two peg-shaped sealing projections 22 are provided on the pressure channel 8, which limit a V-shaped sealing bead 23, in which engages a arranged on the valve plate 2 pin-shaped sealing extension 22.
- sealing beads 23 are arranged on the valve plate 2, in which the two arranged on the pressure channel 8 sealing projections 22 engage, so that comes to a kind of teeth between the pressure channel or suction channel forming components 8,9 and the valve plate 2.
- the cone-shaped sealing projections 22 are provided at their free end region with a chamfer.
- Fig.27 to 31 show developments of the sealing system just described, wherein the peg-shaped sealing projections 22 are executed rounded at its free end.
- the sealing system according to the invention can be used both in the cylinder heads described in this application according to the invention as well as in cylinder heads according to the prior art, ie using cylinder covers. In the latter case, the cylinder cover the sealing extension 22 and the sealing bead 23 and the valve plate 2, the corresponding counterpart.
- FIGS. 32 to 35 show an additional alternative embodiment of a cylinder head with the components 8,9.
- the valve plate 2 is, with the exception of the suction or pressure bore 16.10 coated with a plastic jacket 25 which faces away from the cylinder housing 1 and a cylinder housing facing portion.
- Those components forming the pressure or suction channel 8, 9 are integrated into the plastic layer 25, ie. are also made of plastic.
- the production takes place in this case in several steps.
- valve plate 2 with plastic 25 overmolded (insert technology), wherein on the side facing away from the cylinder housing 1 of the valve plate 2 already pins 28, which serve for positional positioning of the pressure valve 15 (corresponding to the receiving devices 19), are sprayed with.
- valve plate 2 The attachment of the valve plate 2 on the cylinder housing 1 by means of clamping element 7, as already in the previous embodiments.
- Fig.36 and 37th show a variant of a cylinder head, in which in addition to the clamping element 7, a further clamping element 29 is provided. This is according to the invention attached to the clamping element 7 and locked with this.
- a pressure valve 15 forming, plate-shaped element 30, preferably made of metal is provided, which is clamped by the clamping element 7 to the valve plate 2.
- the opening limit 26 for the pressure valve 15 is, as already in Figure 21 or 35 shown, integrated in the component 8.
- the components 8,9 are made in this case as a one-piece plastic part.
- the components 8, 9 are adhesively bonded to the valve plate 2, the pressure valve 15 in this case being arranged in the component 8, as already described above.
- Fig.39 shows the orientation of the pressure valve 15, as a leaf spring, relative to the valve plate 2, wherein the components 8.9 have been omitted to illustrate the readability of the drawing.
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Abstract
Description
Die vorliegende Erfindung betrifft einen hermetisch gekapselten Kältemittelverdichter mit einem hermetisch dichten Verdichtergehäuse, in dessen Innerem eine ein Kältemittel verdichtende Kolben-Zylinder-Einheit arbeitet, deren Zylindergehäuse mittels einer eine Druckbohrung und eine Saugbohrung aufweisenden Ventilplatte verschlossen ist und ein Saugkanal sowie ein Druckkanal vorgesehenen sind, über welche Kältemittel über ein Saugventil in die Saugbohrung gesaugt sowie über ein Druckventil aus der Druckbohrung in den Druckkanal verdichtet wird, wobei der Saugkanal von einem kanalförmigen Bauteil gebildet ist, welcher entlang einer Saugkontaktkante dicht mit der Ventilplatte verbunden ist und die Saugbohrung mit einem vorzugsweisen vorgesehenen Saugschalldämpfer verbindet, gemäß dem Oberbegriff des Anspruchs 1 oder 2.The present invention relates to a hermetically sealed refrigerant compressor with a hermetically sealed compressor housing, in the interior of which a refrigerant-compressing piston-cylinder unit operates, whose cylinder housing is closed by means of a pressure bore and a suction bore having valve plate and a suction channel and a pressure channel are provided via which refrigerant is sucked via a suction valve in the suction hole and compressed via a pressure valve from the pressure bore into the pressure channel, wherein the suction channel is formed by a channel-shaped component which is sealed along a Saugkontaktkante with the valve plate and the suction hole provided with a preferred Suction muffler connects, according to the preamble of
Solche Kältemittelverdichter sind seit langem bekannt und kommen vorwiegend in Kühlschränken oder -regalen zum Einsatz. Dementsprechend hoch ist die jährlich produzierte Stückzahl.Such refrigerant compressors have long been known and are mainly used in refrigerators or shelves. Accordingly high is the annually produced quantity.
Obwohl die Energieaufnahme eines einzelnen Kältemittelverdichters nur etwa zwischen 50 und 150 Watt beträgt, ergibt sich bei Betrachtung sämtlicher, weltweit im Einsatz stehender Kältemittelverdichter ein sehr hoher Energieverbrauch, der aufgrund der zügig voranschreitenden Entwicklung der sogenannten Entwicklungsländer stetig zunimmt.Although the energy consumption of a single refrigerant compressor is only between 50 and 150 watts, when considering all refrigerating compressors in use worldwide, a very high energy consumption results, which steadily increases due to the rapid development of so-called developing countries.
Jede technische Verbesserung, die an einem Kältemittelverdichter vorgenommen wird und dessen Wirkungsgrad erhöht, birgt somit, auf die weltweit im Einsatz befindlichen Kältemittelverdichter hochgerechnet, ein enormes Einsparungspotential an Energie.Any technical improvement that is made to a refrigerant compressor and increases its efficiency, thus, brings to the world in use Extrapolated refrigerant compressors, an enormous savings potential of energy.
Der Kältemittelprozess als solches ist seit langem bekannt. Das siedende Kältemittel wird dabei durch Energieaufnahme aus dem zu kühlenden Raum im Verdampfer verdampft und schließlich überhitzt und mittels des Kältemittelverdichters auf ein höheres Energieniveau gepumpt, wo es Wärme über einen Kondensator abgibt und über eine Drossel, in der eine Druckreduzierung und die Abkühlung des Kältemittels erfolgt, wieder zurück in den Verdampfer befördert wird.The refrigerant process as such has long been known. The boiling refrigerant is vaporized by energy absorption from the space to be cooled in the evaporator and finally superheated and pumped by the refrigerant compressor to a higher energy level, where it emits heat through a condenser and via a throttle, in which a pressure reduction and the cooling of the refrigerant , is transported back to the evaporator.
Das größte und wichtigste Potential für eine mögliche Verbesserung des Wirkungsgrades liegt in der Absenkung der Temperatur des Kältemittels am Beginn dessen Kompressionsvorganges also beim Ansaugen in den Zylinder der Kolben-Zylinder-Einheit. Jede Absenkung dieser sogenannten Saugtemperatur bewirkt daher ebenso wie die Absenkung der Temperatur während des Verdichtungsvorganges und damit verbunden der Ausschiebetemperatur eine Verringerung der erforderlichen Arbeit für den Verdichtungsvorgang.The biggest and most important potential for a possible improvement in the efficiency lies in the lowering of the temperature of the refrigerant at the beginning of its compression process so when sucking into the cylinder of the piston-cylinder unit. Each reduction of this so-called suction temperature therefore causes as well as the lowering of the temperature during the compression process and, associated with the Ausschiebetemperatur a reduction in the required work for the compression process.
Bei bekannten hermetischen Kältemittelverdichtern nach dem Stand der Technik erfolgt bauartbedingt eine starke Erwärmung des Kältemittels auf dessen Weg vom Verdampfer (Kühlraum) zum Ansaugventil der Kolben-Zylinder-Einheit.In known hermetic refrigerant compressors according to the prior art is due to design a strong heating of the refrigerant on its way from the evaporator (refrigerator) to the intake valve of the piston-cylinder unit.
Das Ansaugen des Kältemittels erfolgt über einen direkt vom Verdampfer kommenden Saugkanal während eines Ansaugtaktes der Kolben-Zylinder-Einheit. Von diesem Saugkanal wird das Kältemittel über einen Saugschalldämpfer und ein Saugventil in das Innere des Zylinders gesaugt, wo es durch den Kolben verdichtet und über ein Druckventil aus dem Inneren des Zylinders in einen zum Kühlraum führenden Druckkanal ausgeschoben wird. Bekannte Kältemittelverdichter besitzen dabei einen Aufbau, bei welchem das den Kolben beherbergende Zylindergehäuse durch eine die Saug- bzw. Druckbohrung aufweisende Ventilplatte abgeschlossen ist. Die Ventilplatte dient als Sitz für einen Zylinderdeckel, der in der Regel mit der Ventilplatte und dem Zylindergehäuse verschraubt ist. Der Zylinderdeckel besitzt Zwischenwände, welche den Hohlraum zwischen Zylinderdeckel und Ventilplatte in Kammern unterteilen, welche in weiterer Folge den Saug- bzw. Druckkanal bilden, über welche das Kältemittel in den Zylinder gesaugt bzw. aus diesem ausgeschoben wird.The suction of the refrigerant via a directly coming from the evaporator suction during an intake stroke of the piston-cylinder unit. From this suction channel, the refrigerant is sucked via a suction muffler and a suction valve into the interior of the cylinder, where it is compressed by the piston and a pressure valve from the interior of the cylinder in a pressure chamber leading to the refrigerator is ejected. Known refrigerant compressors have a structure in which the piston housing the cylinder housing is completed by a suction or pressure bore having valve plate. The valve plate serves as a seat for a cylinder cover, which is usually bolted to the valve plate and the cylinder housing. The cylinder cover has intermediate walls which divide the cavity between the cylinder cover and the valve plate into chambers, which subsequently form the suction or pressure channel, via which the refrigerant is sucked into the cylinder or pushed out of it.
Der Saugkanal mündet in der Regel direkt in das Innere des hermetisch dicht gekapselten Verdichtergehäuses in die Nähe der Eintrittsöffnung in einen Saugschalldämpfer, welcher das Ansauggeräusch der Kolben-Zylinder-Einheit reduziert und in der Regel aus mehreren, miteinander in Verbindung stehenden Volumina aufgebaut ist, sowie die erwähnte Eintrittsöffnung aufweist und eine Austrittsöffnung, die dicht an der Saugbohrung der Ventilplatte anliegt.The suction channel usually opens directly into the interior of the hermetically sealed compressor housing in the vicinity of the inlet opening in a suction muffler, which reduces the intake noise of the piston-cylinder unit and is usually constructed of a plurality of interconnected volumes, as well as having the aforementioned inlet opening and an outlet opening which bears tightly against the suction bore of the valve plate.
Neben der erwähnten Einmündung des Saugrohres in das Verdichtergehäuse in der Nähe der Eintrittsöffnung in den Saugschalldämpfer sind auch Ausführungsvarianten bekannt, beispielsweise aus der
Sämtliche bekannten Kältemittelverdichter weisen jedenfalls einen identischen Aufbau der Kolben-Zylinder-Einheit auf, insbesondere des Zylindergehäuses, das mit einer Ventilplatte und einem daran anschließenden Zylinderdeckel verschlossen ist. Der Zylinderdeckel deckt dabei vorzugsweise die gesamte Ventilplatte ab, welche auch die Saugbohrung sowie die Druckbohrung aufweist. An der Ventilplatte sind auch das die Saugbohrung temporär verschließende Saugventil und das die Druckbohrung temporär verschließende Druckventil angeordnet. Der Zylinderdeckel ist in der Regel mit einer Ausnehmung für den Saugkanal, bzw. für den Endabschnitt des Saugschalldämpfers versehen, welcher in die Saugbohrung mündet.Any known refrigerant compressor in any case have an identical structure of the piston-cylinder unit, in particular of the cylinder housing, which is closed with a valve plate and an adjoining cylinder cover. The cylinder cover preferably covers the entire valve plate, which also has the suction bore and the pressure bore. On the valve plate and the suction hole temporarily closing suction valve and the pressure bore temporarily occluding pressure valve are arranged. The cylinder cover is usually provided with a recess for the suction channel, or for the end portion of the suction muffler, which opens into the suction hole.
Das durch den Verdichtungsvorgang erhitzte Kältemittel wird über das Druckventil und die Druckbohrung aus dem Zylinder in den Zylinderdeckel gedrückt, wo es aufgrund der Konstruktion des Zylinderdeckels diesen zumindest in dem den Druckkanal bildenden Abschnitt voll ausfüllt und somit auch mit der einen Teil dieses Druckkanals bildenden Ventilplatte in Berührung kommt. Die Temperatur der Ventilplatte entspricht aufgrund dieser Tatsache im wesentlichen der Temperatur des verdichteten Kältemittels. Da das Gas im Inneren des Zylinders über mehr als 300° Kurbelwinkel kälter als die Ventilplatte ist, kommt es zu einem Wärmestrom von direkt der Ventilplatte oder indirekt von der Ventilplatte zur Zylinderwand und von dort zum Gas im Inneren des Zylinders, was sich negativ auf die Energieeffizienz auswirkt.The heated by the compression process refrigerant is forced through the pressure valve and the pressure bore from the cylinder in the cylinder cover, where it completely fills at least in the pressure channel forming portion due to the construction of the cylinder cover and thus with the part of this pressure channel forming valve plate in Touch comes. The temperature of the valve plate corresponds due to this fact substantially the temperature of the compressed refrigerant. Since the gas in the interior of the cylinder over more than 300 ° crank angle is colder than the valve plate, there is a heat flow from directly the valve plate or indirectly from the valve plate to the cylinder wall and from there to the gas inside the cylinder, which adversely affects the Energy efficiency.
Des weiteren bewirkt die im Zylinderdeckel vorherrschende hohe Temperatur auch einen Wärmefluss in Richtung Endabschnitt des Saugschalldämpfers, der ja vom Zylinderdeckel umgeben ist, wodurch aber das vom Saugschalldämpfer kommende, noch zu verdichtende Kältemittel ebenfalls unerwünschterweise erhitzt wird. Zusammenfassend kann somit gesagt werden, dass die bekannten Kältemittelverdichterkonstruktionen aufgrund ihrer Zylinderdeckelkonstruktion der eingangs erwähnten Zielsetzung, nämlich einer Reduktion der Saugtemperatur sowie der Ausschiebetemperatur, zuwiderlaufen.Furthermore, the high temperature prevailing in the cylinder cover also causes a heat flow in the direction of the end section of the suction muffler, which is indeed surrounded by the cylinder cover, whereby, however, the refrigerant coming from the suction muffler, which is still to be compressed, is also undesirably heated. In summary, it can thus be said that the known refrigerant compressor designs due to their cylinder cover construction of the initially mentioned objective, namely a reduction of the suction temperature and the Ausschiebetemperatur, run counter.
Es ist nun Aufgabe der Erfindung, ein Ausströmen des Kältemittels aus den Kanälen in das Innere des Verdichtergehäuses garantiert unterbinden zu können. Das soll eine signifikante Reduktion der Saugtemperatur sowie der Ausschiebetemperatur unterstützen. Insbesondere ist es eine Aufgabe der Erfindung Saug- bzw. Druckkanal verlässlich hermetisch dicht mit der Ventilplatte zu verbinden.It is an object of the invention to be able to reliably prevent leakage of the refrigerant from the channels into the interior of the compressor housing. This should support a significant reduction of the suction temperature and the discharge temperature. In particular, it is an object of the invention to connect suction or pressure channel reliably hermetically sealed with the valve plate.
Erfindungsgemäß wird dies durch die kennzeichnenden Merkmale des Anspruchs 1 oder 2 ermöglicht.This is made possible by the characterizing features of
Die kennzeichnenden Merkmale der Ansprüche 1 oder 2 beschreiben eine bevorzugte Ausführungsvariante der dichten Anbindung der den Saug- bzw. Druckkanal bildenden Bauteile an die Ventilplatte, um ein Ausströmen des Kältemittels aus den Kanälen in das Innere des Verdichtergehäuses garantiert unterbinden zu können. Die Ausbildung der Dichtsicke in Verbindung mit den Dichtfortsätzen bedingt eine wesentlich geringere erforderliche Presskraft zwischen Druck- bzw. Saugkanal und Ventilplatte als dies zwischen Zylinderdeckel und Ventilplatte bei bekannten Zylinderköpfen der Fall ist.The characterizing features of
Die oben beschriebenen, bekannten Ausführungsvarianten haben außerdem den Nachteil, dass sich das Kältemittel auf seinem Weg vom Eintritt in das Innere des Verdichtergehäuses zur Saugbohrung zu stark erwärmt. Messungen haben ergeben, dass zwischen einem Punkt im Saugkanal kurz vor dem Eintritt in das Verdichtergehäuse und dem ersten Volumen des Saugschalldämpfers eine Erwärmung um mehr als 20°C stattfindet. Der Hauptverursacher dieser unerwünschten Erwärmung des Kältemittels ist die Tatsache, dass das frisch aus dem Saugkanal in das Verdichtergehäuse strömende Kältemittel mit bereits im Verdichtergehäuse befindlichem Kältemittel vermischt wird. Dieses hat jedoch aufgrund der von der Kolben-Zylinder-Einheit im Betrieb abgegebenen Wärme eine höhere Temperatur als das aus dem Saugkanal in das Verdichtergehäuse einströmende Kältemittel, so dass sich bei Vermischung der beiden Kältemittelströme eine Mischtemperatur einstellt, die jedenfalls höher ist als die Temperatur des Kältemittels im Saugkanal vor Eintritt in das Verdichtergehäuse. Verursacher der Mischung ist die Tatsache, dass das an der Ventilplatte sitzende, die Saugbohrung abwechselnd verschließende und freigebende Ansaugventil die Saugbohrung lediglich über einen Kurbelwellenwinkelbereich von 180° freigibt und daher lediglich innerhalb dieses Zeitfensters Kältemittel in den Zylinder der KolbenZylindereinheit gesaugt werden kann. Während des anderen 180° Kurbelwellenwinkelbereichs, dem Verdichtungszyklus, ist das Saugventil zwar geschlossen, das vom Verdampfer kommende Kältemittel weist jedoch einen beinahe konstanten Massenstrom auf, sodass es auch bei geschlossenem Saugventil in das Verdichtergehäuse nachströmt und dort verweilt und die Kolben-Zylinder-Einheit kühlt und sich dabei erwärmt. Dazu kommen durch die Druckschwingungen während der Verdichtungsphase weitere Strömungsvorgänge vom Verdichtergehäuse zum Saugschalldämpfer und umgekehrt, wodurch eine zusätzliche Vermischung der Kältemittel bewirkt wird.The known embodiments described above also have the disadvantage that the refrigerant heats up too much on its way from the inlet to the interior of the compressor housing to the suction bore. Measurements have shown that between a point in the suction channel shortly before entering the compressor housing and the first volume of the suction muffler, a heating by more than 20 ° C takes place. The main cause of this undesirable Heating of the refrigerant is the fact that the fresh refrigerant flowing from the suction channel into the compressor housing is mixed with refrigerant already in the compressor housing. However, this has due to the output from the piston-cylinder unit heat during operation, a higher temperature than the refrigerant flowing from the suction channel in the compressor housing refrigerant, so that when mixing the two refrigerant streams adjusts a mixing temperature, which is certainly higher than the temperature of the Refrigerant in the suction channel before entering the compressor housing. The cause of the mixture is the fact that the seated on the valve plate, the suction hole alternately occlusive and releasing intake valve releases the suction only over a crankshaft angle range of 180 ° and therefore only within this time window refrigerant can be sucked into the cylinder of the piston-cylinder unit. While the intake valve is closed during the other 180 ° crankshaft angle range, the compression cycle, the refrigerant coming from the evaporator has an almost constant mass flow, so that it flows into the compressor housing even with the suction valve closed and lingers and cools the piston-cylinder unit and warmed up. In addition, due to the pressure oscillations during the compression phase, further flow processes from the compressor housing to the suction silencer and vice versa, whereby an additional mixing of the refrigerant is effected.
Daher ist gemäß Anspruch 2 auch ein unabhängiger Bauteil vorgesehen, welcher den Druckkanal bildet und diesen vollständig ummantelt. Durch direktes Verbinden dieses Bauteils mit der Druckbohrung erfolgt eine komplette thermische Trennung des Druckkanals von der Ventilplatte. Diese Bauteile ermöglichen das direkte Austreten des heißen, verdichteten Kältemittels über die Druckbohrung in den Druckkanal, ohne entlang eines Abschnitts der Ventilplatte abströmen zu müssen. Lediglich der unmittelbar die Druckbohrung umgebende Bereich der Ventilplatte kommt an deren dem Kolben abgewandter Seite mit dem heißen Kältemittel in Kontakt. Dadurch kann der Wärmeübergang vom heißen, bereits verdichteten Kältemittel auf die Ventilplatte gegenüber herkömmlichen Zylinderköpfen bei Kältemittelverdichtern drastisch reduziert werden. Die Ventilplatte und die Zylinderwand bleiben kühler und ermöglichen dadurch eine Ableitung der Wärme aus dem Inneren des Zylindergehäuses, bzw. verhindern den Zufluss von Wärme in das Gas im Zylinder. Weiters kann auf diese Art und Weise auch der Wärmeübergang von der Ventilplatte auf die Saugbohrung und damit in den Saugkanal verringert werden, wodurch die Ansaugtemperatur abgesenkt werden kann.Therefore, according to
Durch die kennzeichnenden Merkmale des Anspruchs 4 kann jener Bereich des Druckkanals, welcher auf die Ventilplatte auftrifft, also jener Bereich der innerhalb der Druckkontaktkante liegt, genau dimensioniert werden und hinsichtlich Wärmeübergang optimiert werden. Dabei ist es einerseits erforderlich, dass die Druckbohrung innerhalb dieses Bereichs liegt und andererseits der Übergang zwischen Druckkanal und Druckbohrung strömungsgünstig ausgebildet ist und trotzdem eine dichte Verbindung ermöglicht. Da erfindungsgemäß der Druckkanal bzw. genauer der letzte Abschnitt dieser Kanäle im wesentlichen rechtwinkelig auf die Druckbohrung und somit auf die Ventilplatte auftrifft, um einen Wärmeübergang von der Ventilplatte auf den Druckkanal bzw. umgekehrt zu verhindern, kann die Form der Druckkontaktkante so gewählt werden, dass das Kältemittel die Ventilplatte lediglich entlang einer geringen Fläche umströmt.By the characterizing features of
Erfindungsgemäß ist dabei vorgesehen, dass das Verhältnis der Querschnittsfläche der Druckbohrung zu der durch die Druckkontaktkante umschlossenen Fläche mehr als 1/12 beträgt.According to the invention it is provided that the ratio of the cross-sectional area of the pressure bore to the through Pressure contact edge enclosed area is more than 1/12.
Gemäß den kennzeichnenden Merkmalen des Anspruchs 6 weist der den Druckkanal bildende Bauteil einen unmittelbar an die Druckbohrung anschließenden, von der Ventilplatte wegführenden Abschnitt auf und einen an diesen Abschnitt anschließenden weiteren Abschnitt, der bezogen auf die Zylinderbohrung radial nach außen, vorzugsweise in einem Abstand zur Ventilplatte vorzugsweise parallel dazu verläuft. Dadurch kann das verdichtete Kältemittel rasch von der Ventilplatte weg befördert werden und dessen Wärmeabgabe an die Ventilplatte verhindert bzw. reduziert werden.According to the characterizing features of
Gemäß den kennzeichnenden Merkmalen des Anspruchs 7 ist vorgesehen, dass der von der Ventilplatte wegführende Abschnitt und/oder der weitere Abschnitt des Druckkanals aus schlecht leitendem Kunststoff gefertigt ist/sind, wodurch die Wärmeabgabe des verdichteten Kältemittels nochmals verringert werden kann.According to the characterizing features of
Gemäß den kennzeichnenden Merkmalen des Anspruchs 8 ist des weiteren vorgesehen, dass zwischen dem weiteren Abschnitt und der Ventilplatte ein Isoliermaterial, vorzugsweise aus Gummi oder aus Kunststoff angeordnet ist, um den Wärmeübergang vom verdichteten Kältemittel auf die Ventilplatte noch weiter zu reduzieren.According to the characterizing features of
Die kennzeichnenden Merkmale des Anspruchs 9, nämlich die einstückige Fertigung eines jeden Bauteils bzw. die gemeinsame einstückige Fertigung der beiden den Druck- bzw. Saugkanal bildenden Bauteile, wobei in letzterem Fall sich die beiden gemeinsam einstückig gefertigten Bauteile zumindest entlang einer Zwischenwand berühren, bringt den Vorteil einer vereinfachten Fertigung. So kann der die beiden Kanäle umfassende Bauteil beispielsweise spritzgusstechnisch aus Kunststoff gefertigt werden, wodurch auch der Wärmeübergang aus dem Druckkanal in das Innere des Verdichtergehäuses, aus dem Inneren des Verdichtergehäuses in den Saugkanal sowie im Bereich der Saug- bzw. Druckkontaktkante in die Ventilplatte nochmals verringert werden kann.The characterizing features of
Die kennzeichnenden Merkmale des Anspruchs 10 sehen vor, dass das die Druckbohrung verschließende Druckventil in dem den Druckkanal bildenden Bauteil angeordnet ist. Dadurch kann die Ventilplatte einfacher, dh. in weniger Arbeitsschritten gefertigt werden, da das Vorsehen einer Befestigung für das Druckventil in der Ventilplatte nicht mehr erforderlich ist. Gleichzeitig ermöglicht die Verwirklichung dieses Merkmal ein pre-assembling von Druckkanal und Druckventil bzw. gemeinsam mit den Merkmalen des Anspruchs 10 ein pre-assembling von Druckkanal und Druckventil samt Saugkanal.The characterizing features of
Gemäß den kennzeichnenden Merkmalen der Ansprüche 11 und 12, nämlich der Ausbildung einer Druckkammer im Druckkanal unmittelbar im Anschluss an die Druckbohrung können Drucküberhöhungen im Druckkanal beim Ausschieben des Kältemittels aus dem Zylinder vermieden werden, was zu einer Reduktion der Energieeffizienz führen würde.According to the characterizing features of
Gemäß den kennzeichnenden Merkmalen der Ansprüche 13, 14 und 15 erfolgt die Befestigung der Ventilplatte am Zylindergehäuse mittels eines Klemmelementes, welches die Ventilplatte zumindest entlang eines Abschnittes deren Umfangs, vorzugsweise jedoch entlang des gesamten Umfanges gegen das Zylindergehäuse klemmt. Durch diese Maßnahme kann die Verformung und die Kosten der Zylinderform gegenüber herkömmlichen Zylinderköpfen von Kältemittelverdichtern drastisch verringert werden, da keinerlei Schrauben zur Befestigung der Ventilplatte am Zylindergehäuse mehr erforderlich sind.According to the characterizing features of
Das Klemmelement ist dabei gemäß den kennzeichnenden Merkmalen des Anspruchs 16 mit einem Endabschnitt am Zylindergehäuse vorgesehenen Hinterschneidungen verrastbar.The clamping element is latched according to the characterizing features of
Gemäß den kennzeichnenden Merkmalen des Anspruchs 17 erfolgt mit dem anderen Endabschnitt, der einen ersten Klemmschenkel bildet, die Klemmung der Ventilplatte gegen das Zylindergehäuse.According to the characterizing features of
Das Zylindergehäuse kann des weiteren mit einem Absatz versehen sein, in welchem die Ventilplatte zumindest teilweise versenkt ist, um eine Positionierung derselben zu ermöglichen, da eine Positionierung, wie sie durch Verschraubung bei herkömmlichen Zylinderköpfen von Kältemittelverdichtern bekannt ist, aufgrund der Klemmung nicht mehr möglich ist, wobei eine bevorzugte Ausführungsvariante vorsieht, dass die jene dem Kolben abgewandte Oberfläche der Ventilplatte bündig mit dem Zylindergehäuse abschließt.The cylinder housing may be further provided with a step in which the valve plate is at least partially recessed to allow positioning thereof, since positioning, as known by screwing in conventional cylinder heads of refrigerant compressors, due to the clamping is no longer possible , wherein a preferred embodiment provides that those facing away from the piston surface of the valve plate is flush with the cylinder housing.
Gemäß den kennzeichnenden Merkmalen des Anspruchs 18 erfolgt die Befestigung der den Saug- bzw. Druckkanal bildenden Bauteile an der Ventilplatte mittels weiterer am Klemmelement angeordneter Klemmschenkel. Somit kann gänzlich auf den Einsatz von Schrauben zur Befestigung des Zylinderkopfes verzichtet werden.According to the characterizing features of
Alternativ dazu kann gemäß kennzeichnendem Merkmal des Anspruchs 19 vorgesehen sein, dass ein separates weiteres Klemmelement vorgesehen ist, welches die den Saug- bzw. Druckkanal bildenden Bauteile an der Ventilplatte klemmt, wobei dieses separate Klemmelement mit dem Klemmelement verrastbar ist.Alternatively, it may be provided according to the characterizing feature of
Die kennzeichnenden Merkmale der Ansprüche 20 bis 22 beschreiben eine weitere bevorzugte Ausführungsformen der Erfindung demnach die Ventilplatte mittels separater Befestigungselemente, beispielsweise Schrauben, am Zylindergehäuse befestigt ist, jedoch die den Druck- bzw. Saugkanal bildenden Bauteile an die Ventilplatte geklemmt sind, somit eine Kombination von Klemmung und Verschraubung.The characterizing features of
Im Anschluss erfolgt nun eine detaillierte Beschreibung der Erfindung anhand von Ausführungsbeispielen. Dabei zeigt:
- Fig.1
- eine axonometrische Ansicht einer Kolben-Zylinder-Einheit samt erfindungsgemäßem Zylinderkopf
- Fig.2
- eine Frontansicht eines Zylinderkopfes
- Fig.3
- eine axonometrische Ansicht einer Kolben-Zylinder-Einheit samt Zylinderkopf ohne Klemmelement
- Fig.4
- eine axonometrische geschnittene Detailansicht eines Zylinderkopfs
- Fig.5
- eine Sicht in Richtung Kurbelwellenachse auf einen Zylinderkopf samt Zylindergehäuse und Kurbelwellengehäuse
- Fig.6
- einen Schnitt entlang Linie AA aus
Fig.2 - Fig.7
- eine Sicht in Richtung Kurbelwellenachse auf einen Zylinderkopf samt Zylindergehäuse und Kurbelwellengehäuse ohne Klemmelement
- Fig. 8
- eine axonometrische Ansicht des den Druckkanal bildenden Bauteils
- Fig.8a
- eine axonometrische Ansicht des den Druckkanal bildenden Bauteils im Schnitt
- Fig.9
- eine alternative Ausführungsvariante eines erfindungsgemäßen Zylinderkopfes
- Fig.10
- eine Schnittansicht der alternativen Ausführungsvariante aus
Fig.9 entlang der Ebene A1 ausFig.9 - Fig.11
- eine Detailansicht aus
Fig.10 - Fig.12
- eine Schnittansicht entlang der Ebene A aus
Fig.9 - Fig.13
- eine weitere alternative Ausführungsvariante eines Zylinderkopfes
- Fig.14
- eine Schnittansicht entlang Ebene B aus
Fig.13 - Fig.15
- eine zusätzliche alternative Ausführungsvariante eines Zylinderkopfes
- Fig.16
- eine Schnittansicht entlang Ebene C aus
Fig.15 - Fig.17
- eine andere alternative Ausführungsvariante eines Zylinderkopfes
- Fig.18
- eine Schnittansicht entlang Ebene D aus
Fig.17 - Fig.19
- eine Schnittansicht eines Zylinderkopfes mit O-Ringdichtung
- Fig.20
- eine Schnittansicht eines Zylinderkopfes mit Papierdichtung
- Fig.21
- eine Darstellung eines erfindungsgemäßen Dichtsystems im Schnitt entlang Ebene E aus
Fig.22 - Fig.22
- eine zusätzliche, weitere Ausführungsvariante eines erfindungsgemäßen Zylinderkopfs gemäß
Fig.21 - Fig.23
- eine Schnittansicht entlang Ebene F aus
Fig.22 - Fig.24-31
- Schnittansichten eines alternativen, erfindungsgemäßen Dichtungssystems
- Fig.32
- eine zusätzliche, alternative Ausführungsvariante eines Zylinderkopfes
- Fig.33
- eine Schnittansicht entlang Ebene G aus
Fig.32 - Fig.34
- eine Draufsicht auf einen Zylinderkopf gem.
Fig.32 - Fig.35
- eine Schnittansicht entlang Ebene H aus
Fig.34 - Fig.36
- eine weiteres Ausführungsbeispiel eines Zylinderkopfes
- Fig.37
- eine axonometrische Ansicht des Zylindergehäuses samt Klemmelement gemäß
Fig.36 - Fig.38
- eine weiteres Ausführungsbeispiel eines Zylinderkopfes
- Fig.39
- das Ausführungsbeispiel gemäß
Fig.38 ohne den Druck-bzw. Saugkanal bildende Bauteile
- Fig.1
- an axonometric view of a piston-cylinder unit including cylinder head according to the invention
- Fig.2
- a front view of a cylinder head
- Figure 3
- an axonometric view of a piston-cylinder unit including cylinder head without clamping element
- Figure 4
- an axonometric sectional detail view of a cylinder head
- Figure 5
- a view in the direction of the crankshaft axis on a cylinder head including the cylinder housing and the crankcase
- Figure 6
- a section along line AA
Fig.2 - Figure 7
- a view in the direction of the crankshaft axis on a cylinder head including the cylinder housing and crankcase without clamping element
- Fig. 8
- an axonometric view of the pressure channel forming member
- Figure 8a
- an axonometric view of the pressure channel forming member in section
- Figure 9
- an alternative embodiment of a cylinder head according to the invention
- Figure 10
- a sectional view of the alternative embodiment of
Figure 9 along the A1 levelFigure 9 - fig.11
- a detailed view
Figure 10 - Figure 12
- a sectional view taken along the plane A from
Figure 9 - Figure 13
- a further alternative embodiment of a cylinder head
- Figure 14
- a sectional view along plane B from
Figure 13 - Figure 15
- an additional alternative embodiment of a cylinder head
- Figure 16
- a sectional view along plane C from
Figure 15 - Figure 17
- another alternative embodiment of a cylinder head
- Figure 18
- a sectional view along plane D from
Figure 17 - Figure 19
- a sectional view of a cylinder head with O-ring seal
- fig.20
- a sectional view of a cylinder head with paper seal
- Figure 21
- an illustration of a sealing system according to the invention in section along plane E.
Figure 22 - Figure 22
- an additional, further embodiment of a cylinder head according to the invention according to
Figure 21 - Figure 23
- a sectional view along plane F from
Figure 22 - Fig.24-31
- Sectional views of an alternative sealing system according to the invention
- fig.32
- an additional, alternative embodiment of a cylinder head
- fig.33
- a sectional view along plane G from
fig.32 - Fig.34
- a plan view of a cylinder head gem.
fig.32 - Fig.35
- a sectional view along plane H from
Fig.34 - Fig.36
- a further embodiment of a cylinder head
- Fig.37
- an axonometric view of the cylinder housing together with clamping element according to
Fig.36 - Fig.38
- a further embodiment of a cylinder head
- Fig.39
- the embodiment according to
Fig.38 without the pressure resp. Suction channel forming components
Der grundsätzliche Aufbau des gegenständlichen hermetisch gekapselten Kältemittelverdichters ist an und für sich bekannt. Die Kolben-Zylinder-Motor-Einheit besteht im wesentlichen aus einem Zylindergehäuse 1 sowie dem darin eine Hubbewegung vollführenden Kolben 4, sowie einem Kurbelwellenlager 5 in einem Kurbelwellengehäuse 5a, welches senkrecht zur Zylinderachse 6 angeordnet ist. Das Kurbelwellenlager 5 nimmt eine Kurbelwelle (nicht gezeichnet) auf und ragt in eine zentrische Bohrung des Rotors eines Elektromotors (ebenfalls nicht gezeichnet). Die Übertragung der Drehbewegung der Kurbelwelle auf den Kolben 4 erfolgt in ebenfalls bekannter Weise über ein Pleuel (nicht gezeichnet). Am Zylinderkopf selbst ist ein Saugschalldämpfer 3 angeordnet, der beim Ansaugvorgang des Kältemittels die Geräuschentwicklung auf ein Minimum reduzieren soll.The basic structure of the subject hermetically sealed refrigerant compressor is known per se. The piston-cylinder-motor unit consists essentially of a
Der Abstand Z zwischen dem Bauteil 8 und der Ventilplatte 2 bewirkt eine optimale Isolierung der Ventilplatte 2 vom Druckkanal, so dass hier eine Wärmeübertragung vom verdichteten, heißen Kältemittel im Druckkanal 8 auf die Ventilplatte 2 und auf den Saugkanal 9 stark verhindert wird.The distance Z between the
Unmittelbar im Anschluss an die in der Ventilplatte 2 angeordnete Druckbohrung 10, die beispielsweise in
Die Bauteile 8,9 werden, wie aus
Die erfindungsgemäße Anordnung des Druckventils 15 im Bauteil 8 ermöglicht die Vorfertigung dieser beiden Teile entlang einer separaten Fertigungsstrecke. Bauteil 8 samt Druckventil 15 und Öffnungsbegrenzung 26 können dann mittels Klemmelement 7 mit der Ventilplatte 2 einfach und schnell verbunden werden. Die herkömmliche Art der Befestigung des Druckventils 15 an der Ventilplatte 2, beispielsweise durch Nieten ist dann nicht mehr erforderlich, wodurch sich eine wesentliche Vereinfachung und vor allem auch Beschleunigung des Herstellungsprozesses ergibt.The inventive arrangement of the
Das Klemmelement 7 weist einen zusätzlichen Klemmabschnitt 7a auf, der im wesentlichen U-förmig ausgebildet ist und die Bauteile 8,9 gegen die Ventilplatte 2 klemmt.The clamping
Das gleiche gilt selbstverständlich auch für die Saugkontaktkante 17, entlang welcher der Saugkanal 9 dicht mit der Ventilplatte 2 verbunden ist. Innerhalb der von der Saugkontaktkante 17 umschlossenen Fläche befindet sich die Saugbohrung 16. Die von der Saugkontaktkante 17 umschlossene Fläche ist gleichzeitig der einzige Abschnitt der Ventilplatte 2, der mit dem in den Zylinder gesaugten Kältemittel in Berührung kommt.The same naturally also applies to the
Das Zylindergehäuse 1 weist einen Absatz 27 auf, in welchem die Ventilplatte 2 zumindest teilweise, vorzugsweise jedoch gänzlich versenkt ist, wodurch gleichzeitig eine Positionierung der Ventilplatte 2 erreicht wird.The
Die
Selbstverständlich ist auch eine umgekehrte Ausführung denkbar, dh. an der Druckkontaktante 13 des den Druckkanal bildenden Bauteils 8 bzw. an der Saugkontaktkante 17 des den Saugkanal bildenden Bauteils 9 (siehe auch
Um eine Abdichtung der Verbindung zu gewährleisten muss der Dichtfortsatz 22 entweder ein größeres Volumen aufweisen als die Dichtsicke 23 oder aber die Form des Dichtfortsatzes 22 ist eine andere als jene der Dichtsicke 23. Die bei der Montage des Zylinderkopfes angewandten Presskräfte insbesondere auch die Klemmkräfte des Klemmelementes 7 bewirken dann das Fließen des Dichtfortsatzes 22 in der Dichtsicke 23 bzw. von Teilen des Dichtfortsatzes 22 aufgrund der hohen lokalen Flächenpressung.In order to ensure a sealing of the connection, the sealing
Die Ausbildung der Dichtsicke 23 in Verbindung mit den Dichtfortsätzen 22 bedingt bei gleicher Dichtheit eine wesentlich geringere erforderliche Presskraft zwischen Druck- bzw. Saugkanal 8,9 und Ventilplatte 2 als dies zwischen Zylinderdeckel und Ventilplatte 2 bei bekannten Zylinderköpfen der Fall ist. Die notwendige Flächenpressung ist zwar bei beiden Systemen die gleiche, jedoch unterscheiden sich die Dichtflächen ganz wesentlich, nämlich eine lange breite Dichtung im Falle der Papierdichtung und eine kurze schmale Dichtfläche im Falle des Dichtsicke 23 - Dichtfortsatz 22 Systems.The formation of the sealing
Das Dichtsystem funktioniert unabhängig von den eingesetzten Werkstoffpaarungen. So sind herkömmliche Werkstoffpaarungen möglich, wie beispielsweise Metall (Ventilplatte 2) - Metall (Bauteile 8,9) oder aber auch Metall (Ventilplatte 2) - fließfähiger Kunststoff (Bauteile 8,9) oder Kunststoff (Ventilpatte 2) - fließfähiger Kunststoff (Bauteile 8,9).The sealing system works independently of the material pairings used. So conventional material pairings are possible, such as metal (valve plate 2) - metal (
Die für den vorliegenden Anwendungsfall erforderliche Flächenpressung kann dabei mit 5 bis 20 N/mm2 angegeben werden. Eine besonders bevorzugte geometrische Form der Dichtsicke 23 ist die V-form oder U-Form gemäß den
In beiden Fällen ist der zapfenförmige Dichtfortsatz 22 an seinem freien Ende abgeflacht ausgeführt.In both cases, the peg-shaped
In
Das erfindungsgemäße Dichtsystem kann sowohl bei in dieser Anmeldung beschriebenen erfindungsgemäßen Zylinderköpfen zur Anwendung kommen kann als auch bei Zylinderköpfen nach dem Stand der Technik, also unter Einsatz von Zylinderdeckeln. In letzterem Fall, weist der Zylinderdeckel den Dichtfortsatz 22 bzw. die Dichtsicke 23 auf und die Ventilplatte 2 das entsprechende Gegenstück.The sealing system according to the invention can be used both in the cylinder heads described in this application according to the invention as well as in cylinder heads according to the prior art, ie using cylinder covers. In the latter case, the cylinder cover the sealing
Die
Die
Die Herstellung erfolgt in diesem Fall in mehreren Schritten.The production takes place in this case in several steps.
Zunächst wird die Ventilplatte 2 mit Kunststoff 25 umspritzt (Inserttechnik), wobei an der dem Zylindergehäuse 1 abgewandten Seite der Ventilplatte 2 bereits Pins 28, welche zur Lagepositionierung des Druckventiles 15 dienen (entsprechend den Aufnahmevorrichtungen 19), mit aufgespritzt werden.First, the
An der dem Kolben 4 zugewanden Seite wird plan umspritzt. Hier werden keine Haltevorrichtungen für das Saugventil benötigt. Es ist lediglich eine Freistellung für die Lagepositionierung des Saugventiles vorzusehen. Das Saugventil selbst wird zwischen Stirnseite des Zylindergehäuses 1 und Ventilplatte 2 geklemmt.At the
In einem weiteren Schritt wird, um den den Druckkanal bildenden Bauteil 8 sowie den den Saugkanal bildenden Bauteil 9, welche in einem separaten Arbeitsschritt ebenfalls aus Kunststoff hergestellt werden, mit der Ventilplatte 2 zu verbinden, entlang der Dichtsicken 24, die in ihrem Umriss der Druckkontaktkante 13 bzw. Saugkontaktkante 17 entsprechen und in diesem Ausführungsbeispiel nicht in der Ventilplatte 2 angeordnet sind, sondern im die Ventilplatte 2 umgebenden Kunststoffmantel 25, eine Laserschweißung oder Vibrationsschweißung der Kunststoffteile vorgenommen.In a further step, in order to connect the pressure channel-forming
Die Befestigung der Ventilplatte 2 am Zylindergehäuse 1 erfolgt mittels Klemmelement 7, wie auch schon bei den vorherigen Ausführungsvarianten.The attachment of the
Die Bauteile 8,9 sind in diesem Fall als ein einstückiger Kunststoffteil gefertigt.The
In der in
- 1.1.
- Zylindergehäusecylinder housing
- 1a.1a.
- hochgezogener Abschnitt des Zylindergehäusesraised portion of the cylinder housing
- 2.Second
- Ventilplattevalve plate
- 3.Third
- Saugschalldämpfersuction silencer
- 3a.3a.
- Ansaugöffnungsuction
- 4.4th
- Kolbenpiston
- 5.5th
- Kurbelwellenlagercrankshaft bearings
- 5a.5a.
- Kurbelwellengehäusecrankcase
- 6.6th
- Zylinderachsecylinder axis
- 7.7th
- Klemmelementclamping element
- 7a.7a.
- Klemmabschnittclamping section
- 7b.7b.
- Klemmabschnittclamping section
- 8.8th.
- den Druckkanal bildendes Bauteilthe pressure channel forming component
- 8a.8a.
- wegführender Abschnitt des Druckkanals, Druckkammerwegführender section of the pressure channel, pressure chamber
- 8b.8b.
- weiterer Abschnitt des Druckkanalsanother section of the pressure channel
- 9.9th
- den Saugkanal bildendes Bauteilthe suction channel forming component
- 10.10th
- Druckbohrungpressure bore
- 11.11th
- Schraubenscrew
- 12.12th
- ZylinderinnenraumCylinder interior
- 13.13th
- DruckkontaktkantePressure contact edge
- 14.14th
- SchadraumdichtungDead space seal
- 15.15th
- Druckventilpressure valve
- 15a.15a.
- freier Endabschnitt des Druckventilsfree end portion of the pressure valve
- 16.16th
- Saugbohrungsuction bore
- 17.17th
- SaugkontaktkanteSaugkontaktkante
- 18.18th
- Durchbrüchebreakthroughs
- 19.19th
- Aufnahmevorrichtungencradles
- 20.20th
- O-RingdichtungO-ring seal
- 21.21st
- Papierdichtungpaper gasket
- 22.22nd
- DichtfortsatzSealing projection
- 23.23rd
- Dichtsickesealing bead
- 24.24th
- Dichtsickesealing bead
- 25.25th
- KunststoffmantelPlastic sheath
- 26.26th
- ÖffnungsbegrenzungCushioned limit
- 27.27th
- Hinterschneidungundercut
- 28.28th
- Pinspins
- 29.29th
- weiteres Klemmelementanother clamping element
- 30.30th
- plattenförmiges Elementplate-shaped element
- 31.31st
- Absatzparagraph
- 32.32nd
- Saugventilsuction
Claims (22)
- A hermetically encapsulated refrigerant compressor having a hermetically sealed compressor housing, in whose interior a piston-cylinder unit, which compresses a refrigerant, operates, whose cylinder housing (1) is closed using a valve plate (2) having a pressure hole (10) and a suction hole (16), and a suction channel and a pressure channel are provided, via which refrigerant is suctioned via a suction valve (32) into the suction hole (16) and is compressed via a pressure valve (15) from the pressure hole (10) in the pressure channel, the suction channel being formed by a channel-shaped component (9), which is connected sealingly along a suction contact edge (17) to the valve plate (2) and which connects the suction hole (16) to a preferably provided suction noise damper (3), characterized in that preferably V-shaped sealing beads (23) or sealing projections (22) are provided in the valve plate (2) and the front face of the component (9) forming the suction channel, which faces toward the valve plate (2), is equipped along its suction contact edge (17) with sealing projections (22) or sealing beads (23) essentially corresponding to the V-shaped sealing beads (23) or sealing projections (22), whereas the sealing projections (22) being implemented differently from the sealing beads (23) in their geometrical design and/or having a different volume.
- A hermetically encapsulated refrigerant compressor according to Claim 1, characterized in that the pressure channel is formed by an independent component (8) completely enveloping the pressure channel, which is tightly connected to the valve plate (2) along a pressure contact edge (13) formed by an end section of the component (8).
- The hermetically encapsulated refrigerant compressor according to Claim 1 or 2, characterized in that the pressure hole (10) and the movable part of the pressure valve (15) are situated inside the area enclosed by the pressure contact edge (13).
- The hermetically encapsulated refrigerant compressor according to Claim 3, characterized in that the ratio of the cross-sectional area of the pressure hole (10) to the area enclosed by the pressure contact edge (13) is greater than 1/12.
- The hermetically encapsulated refrigerant compressor according to one of Claims 1 through 4, characterized in that the area enclosed by the pressure contact edge (13) exceeds the area of the mobile parts of the pressure valve (15) by less than 50%.
- The hermetically encapsulated refrigerant compressor according to one of Claims 1 through 5, characterized in that the component (8) forming the pressure channel has a section (8a) directly adjoining the pressure hole (10) and leading away from the valve plate (2), and a further section (8b) adjoining this section (8a), which runs radially outward in relation to the cylinder hole, preferably at a distance to the valve plate (2) and preferably parallel thereto.
- The hermetically encapsulated refrigerant compressor according to Claim 6, characterized in that the section (8a) leading away from the valve plate (2) and/or the further section (8b) of the pressure channel (8) is/are manufactured from plastic.
- The hermetically encapsulated refrigerant compressor according to claim 6 or 7, characterized in that an insulating material, preferably made of rubber or plastic, is situated between the further section (8b) and the valve plate (2).
- The hermetically encapsulated refrigerant compressor according to one of Claims 1 through 8, characterized in that the component (8) forming the pressure channel and the component (9) forming the suction channel are each manufactured in one piece and/or are preferably manufactured jointly in one piece, the two components (8, 9) manufactured jointly in one piece preferably being in contact along an intermediate wall, but at least along connecting webs.
- The hermetically encapsulated refrigerant compressor according to one of Claims 1 through 9, characterized in that the pressure valve (15) closing the pressure hole (10) is fastened in the component (8) forming the pressure channel.
- The hermetically encapsulated refrigerant compressor according to one of Claims 1 through 10, characterized in that a pressure chamber (8a), which does not fall below a predefined minimum volume, is provided in the component (8) forming the pressure channel.
- The hermetically encapsulated refrigerant compressor according to Claim 11, characterized in that the pressure chamber (8a) is situated directly adjoining the pressure hole (10) in the component (8) forming the pressure channel.
- The hermetically encapsulated refrigerant compressor according to one of Claims 1 through 12, characterized in that a clamping element (7) is provided, which clamps the valve plate (2) to the cylinder housing (1) along at least a section of its circumference, but preferably along the entire circumference.
- The hermetically encapsulated refrigerant compressor according to Claim 13, characterized in that the clamping element (18) has an essentially J-shaped cross-section.
- The hermetically encapsulated refrigerant compressor according to Claim 13 or 14, characterized in that the clamping element (7) is implemented as circular.
- The hermetically encapsulated refrigerant compressor according to one of Claims 13 through 15, characterized in that one or more undercuts (27), which are engageable with an end section of the clamping element (7), are provided on the cylinder housing (1).
- The hermetically encapsulated refrigerant compressor according to Claim 16, characterized in that the other end section of the clamping element (7) forms a first clamping section (7b), which clamps the valve plate (2) to the cylinder housing (1).
- The hermetically encapsulated refrigerant compressor according to one of Claims 13 through 17, characterized in that the clamping element (7) has at least one further clamping section (7a), which clamps the components (8, 9) forming the pressure channel or the suction channel to the valve plate (2) or in the suction hole (16) and/or the pressure hole (10) respectively.
- The hermetically encapsulated refrigerant compressor according to one of Claims 13 through 18, characterized in that a further clamping element (29) is provided, which is engageable on the clamping element (7) and clamps the components (8, 9) forming the pressure channel or the suction channel to the valve plate (2) or in the suction hole (16) and/or the pressure hole (10) respectively.
- The hermetically encapsulated refrigerant compressor according to one of Claims 1 through 12, characterized in that separate fasteners (11) are provided or a separate fastener (7b) is provided for fastening the valve plate (2) to the cylinder housing (1).
- The hermetically encapsulated refrigerant compressor according to Claim 20, characterized in that the separate fasteners are screws (11).
- The hermetically encapsulated refrigerant compressor according to one of Claims 20 or 21, characterized in that a clamping element is provided, which is engageable on the cylinder housing (3) and clamps the components (8, 9) forming the pressure channel or the suction channel to the valve plate (2) or in the suction hole (16) and/or the pressure hole (10) respectively.
Applications Claiming Priority (3)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
AT0022305U AT8477U1 (en) | 2005-03-31 | 2005-04-12 | REFRIGERANT COMPRESSOR |
AT0005906U AT8985U1 (en) | 2005-03-31 | 2006-01-27 | REFRIGERANT COMPRESSOR |
PCT/EP2006/061196 WO2006108767A1 (en) | 2005-04-12 | 2006-03-30 | Refrigerant compressor |
Publications (2)
Publication Number | Publication Date |
---|---|
EP1869323A1 EP1869323A1 (en) | 2007-12-26 |
EP1869323B1 true EP1869323B1 (en) | 2009-11-11 |
Family
ID=36593060
Family Applications (1)
Application Number | Title | Priority Date | Filing Date |
---|---|---|---|
EP06725444A Not-in-force EP1869323B1 (en) | 2005-04-12 | 2006-03-30 | Refrigerant compressor |
Country Status (6)
Country | Link |
---|---|
US (1) | US20090214367A1 (en) |
EP (1) | EP1869323B1 (en) |
CN (1) | CN101180465B (en) |
AT (1) | ATE448405T1 (en) |
DE (1) | DE502006005341D1 (en) |
WO (1) | WO2006108767A1 (en) |
Families Citing this family (6)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN102297118B (en) * | 2011-09-30 | 2013-10-09 | 黄石东贝电器股份有限公司 | Separate heat-insulating exhaust silencing device and refrigerant compressor adopted thereby |
EP2805055B1 (en) * | 2012-01-20 | 2016-05-25 | Alfred Kärcher GmbH & Co. KG | Piston pump for a high-pressure cleaning device |
KR101854933B1 (en) * | 2013-04-24 | 2018-05-04 | 엘지전자 주식회사 | Muffler for compressor and compressor having the same |
WO2017191228A1 (en) * | 2016-05-05 | 2017-11-09 | Arcelik Anonim Sirketi | A hermetic compressor with increased performance |
KR101951651B1 (en) * | 2017-05-18 | 2019-02-25 | 뉴모텍(주) | Compact Air Compressor |
KR102345324B1 (en) * | 2020-08-28 | 2021-12-31 | 엘지전자 주식회사 | Linear compressor |
Family Cites Families (7)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
DE3332259A1 (en) * | 1983-09-07 | 1985-03-28 | Danfoss A/S, Nordborg | REFRIGERATOR COMPRESSORS |
US5129793A (en) * | 1990-10-24 | 1992-07-14 | Copeland Corporation | Suction muffler |
US5288212A (en) * | 1990-12-12 | 1994-02-22 | Goldstar Co., Ltd. | Cylinder head of hermetic reciprocating compressor |
JP3318415B2 (en) * | 1992-12-21 | 2002-08-26 | エルジー電子株式会社 | Noise reduction device for hermetic reciprocating compressor |
DE19923733C2 (en) * | 1999-05-22 | 2002-06-20 | Danfoss Compressors Gmbh | Suction gas line for a refrigerant compressor |
BR0105694B1 (en) * | 2001-10-29 | 2009-05-05 | suction filter for reciprocating airtight compressor. | |
DE10341138A1 (en) * | 2003-09-06 | 2005-04-07 | Danfoss Compressors Gmbh | Refrigerant compressor has suction path extending as passage in channel element having direction change and which at least in region of direction change has at least one deflection element dividing suction path parallel to passage |
-
2006
- 2006-03-30 DE DE502006005341T patent/DE502006005341D1/en active Active
- 2006-03-30 EP EP06725444A patent/EP1869323B1/en not_active Not-in-force
- 2006-03-30 WO PCT/EP2006/061196 patent/WO2006108767A1/en active Application Filing
- 2006-03-30 US US11/918,285 patent/US20090214367A1/en not_active Abandoned
- 2006-03-30 AT AT06725444T patent/ATE448405T1/en active
- 2006-03-30 CN CN2006800177043A patent/CN101180465B/en not_active Expired - Fee Related
Also Published As
Publication number | Publication date |
---|---|
EP1869323A1 (en) | 2007-12-26 |
WO2006108767A9 (en) | 2007-09-13 |
ATE448405T1 (en) | 2009-11-15 |
CN101180465B (en) | 2011-06-22 |
US20090214367A1 (en) | 2009-08-27 |
WO2006108767A1 (en) | 2006-10-19 |
CN101180465A (en) | 2008-05-14 |
DE502006005341D1 (en) | 2009-12-24 |
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