DE19535079C2 - compressor - Google Patents

Description

The invention relates to a compressor according to the Oberbe handle of claim 1.

Such a compressor is from DE 36 05 935 A1 knows.

This well-known compressor has one made of a cylinder the upper head part and a lower cylinder head part the cylinder head, in which a suction chamber and a pressure space as well as a suction valve and a pressure valve are. A compression space of the compressor is about that Suction valve with the suction chamber and via the pressure valve with connectable to the pressure chamber. The suction room is with a Suction port of the compressor and the pressure chamber is with a pressure connection of the compressor. In the Zy Lindenkopf is a wall-like part transverse to the longitudinal axis of the cylinder head arranged so that it runs Pressure chamber in a first pressure chamber on the pressure valve side and a pressure port side second pressure chamber and Suction chamber in a first suction chamber and suction connection a second suction chamber on the suction valve side. The first suction chamber is on in the wall-like part arranged through opening with the second suction chamber bound and the first pressure chamber is above one in the  Wall-like part arranged further through opening in communication with the second pressure chamber.

By arranging such, serve as a partition the wall-like part should pulsate pressure fluctuations gene can be reduced.

A compressor known from DE 28 26 744 A1 has in the Cylinder head arranged webs, which are in the Extend the pressure chamber and from the Druckventilöff starting from chambers or channels through which the main part of the compressed air inevitably by redirecting the pressure connection one or more times of the compressor is supplied.

By passing the compressed air past the webs achieves cooling of the compressed air and thus also the Cylinder head temperature lowered.

The invention has for its object a compression ter of the type mentioned to improve so that a even better cooling of the air delivered by the compressor is achieved.

This object is specified with that in claim 1 NEN invention solved. Training and advantageous Embodiments of the invention are in the subclaims specified.

The invention offers the advantage in particular with simple Chen means a large cooling surface for the compressor  to get pumped air without the cylinder head of the Need to make major changes to the compressor.

The fact that a wall-like part transverse to the longitudinal axis of the Cylinder head is arranged in the cylinder head so that it the pressure chamber into a first pressure chamber and a second Pressure chamber divided, the two pressure chambers via a through opening in the wall-like part are connected to each other, causing a longer lingering time duration of the compressed air delivered by the compressor under pressure Space is achieved, and in that the wall-like part into a coolant holder additional space in the cylinder head achieved an improvement in the cooling of the compressed air. In addition, by appropriate design of the wandar term part and by appropriate arrangement of the through passage opening in the wall-like part (passage opening and pressure valve arranged offset to each other) the Compressed air targeted to particularly well-cooled points in the Cylinder head.

Not only the pressure chamber, but also the suction chamber of the compressor in two by means of a wall-like part Chambers divided, which through another Durchöfföff in the other wall-like part those are, and are the wall-like parts from one that Heat dissipating material is produced, so a even better and faster cooling of the air in the Compressor achieved. This measure also improved noise reduction achieved. The air can due to the favorable arrangement of the through openings in the  wall-like parts easily to the locations of the cylinder head fes that are particularly hot.

According to an advantageous development of the invention the wall-like part of the one between the cylinder arranged top part of the head and the lower part of the cylinder head Seal formed for this purpose as a plattenar term part is formed, which differs from its on clamping area between the top part of the cylinder head and the Starting cylinder head lower part, transverse to the longitudinal axis of the Upper part of the cylinder head and lower part of the cylinder head running, at least up to the pressure chamber and in the extends the coolant receiving space, thereby the pressure chamber from the seal into a pressure valve side first pressure chamber and a second pressure port side Pressure chamber and the space for the coolant in a first chamber and a second chamber is divided, the two pressure chambers and the two the cooling medium receiving chambers over one each of the seal limited or one each arranged in the seal are connected to each other.

The fact that the seal in the rooms or Ka channels of the compressor, which are caused by a coolant are poured in, stretched into first and divided into two chambers, a particularly good Ab Conduction of heat to the coolant reached. Thereby, that the coolant channels in two through the seal un Partitioned chambers are divided over passage openings in the seal are interconnected, a flow is caused in the coolant channels,  which ent air bubbles in the coolant channels counteracts.

According to a further advantageous development of the Er is the top part of the cylinder head or the cylinder lower part of the head transverse to the longitudinal axis of the cylinder head shares trained. In every part of the cylinder head upper part les or the lower part of the cylinder head is another Wall-like part arranged, making the pressure connection sided second pressure chamber or the pressure valve side first pressure chamber of the pressure chamber or the Saugan end-side first suction chamber or the suction valve side second suction chamber of the suction chamber in several subchambers is divided over in the wall-like parts orderly through openings are interconnected. Will one between the parts of the cylinder head upper part or the lower part of the cylinder head gasket formed as a wall-like part, then the plat ten-shaped seal between each other turned end faces of the two cylinder head or Cylinder head lower parts clamped. The other plates like seal extends at least in the pressure end-side second pressure chamber or in the pressure valve sided first pressure chamber and divides it into a first sub-chamber and a second sub-chamber. The Both subchambers are one above the other device limited or arranged in the further seal Through opening connected together. The pressure valve and the through opening of the first seal and the first wall-like part and this through opening and the through opening of the second seal or second wall-like part are offset from each other arranged. The two plate-like seals or wall-like parts with the diameters defined by them passage openings practically form a labyrinth through which the compressed air coming from the pressure valve to the pressure connection is led.

According to a further development of the invention, it is also possible Lich to form the second seal and so dimensioned sen that they are also in a suction chamber of the suction space and in a cooling chamber of a cold room or in a chamber in another room and these subdivided into sub-chambers, which are accessible through openings in the seal are interconnected.

Based on the drawing, seven versions are shown below tion examples of the invention explained.

Show it:

Fig. 1 shows a longitudinal section through a the OF INVENTION to the invention the wall-like parts containing cylinder head of a compressor, wherein the pressure chamber and the other wall-like part of a first chamber and a second chamber tert approaches a wall-like part of the suction chamber in each un

Fig. 2 is a plan view of the cylinder head of FIG. 1 with the cylinder head removed upper part,

Fig. 3 shows a longitudinal section through the cylinder head having two pressure chamber and the suction chamber dividing wall-like parts,

Fig. 4 shows a longitudinal section through the extension OF INVENTION proper sealing arrangement containing the cylinder head of a compressor, wherein the seal both the pressure chamber and the suction chamber is divided into a respective first chamber and a second chamber,

Fig. 5 is a plan view of the cylinder head shown in FIG. 4 with removed cylinder head upper part,

Fig. 6 shows a longitudinal section through the cylinder head taken along section line BB of FIG. 5,

Fig. 7 is a plan view head cover to the cylinder head according to FIGS. 4 and 6 with removed cylinder, the seal comprising staltungen deviating Starting from that in FIG. Gasket shown 5,

Figure 8 is a longitudinal section circuit. By the dung OF INVENTION proper sealing arrangement containing the cylinder head of a compressor with a laterally arranged on the cylinder head Saugan,

Fig. 9 is a ge from the design of the cylinder head shown in Fig. 8 deviating Ausgestal device of the cylinder head with side pressure and

Fig. 10 is a longitudinal section through a cylinder head which has two plate-like seals.

According to FIG. 1, a piston ( 2 ) is arranged movably in the direction of the longitudinal axis of the cylinder ( 1 ) in a cylinder ( 1 ) of a compressor for generating compressed air. The Zy cylinder ( 1 ) has a compression chamber ( 3 ) which is limited on the one hand by the piston ( 2 ) and on the other hand by a cylinder head ( 33 , 29 ). The cylinder ( 1 ) and the cylinder head Zy ( 33 , 29 ) are means not shown, such as. B. screws or studs mitein connected, wherein a cylinder head gasket ( 6 ) is arranged between the facing sides of the cylinder head ( 33 , 29 ) and cylinder ( 1 ).

The cylinder head ( 33 , 29 ) is formed transversely to the longitudinal axis of the cylinder ( 1 ) divided so that it consists of a Zy cylinder head lower part ( 33 ) and a cylinder head cover serving as the cylinder head upper part ( 29 ). The Zylin derkopfoberteil ( 29 ) and the cylinder head lower part ( 33 ) are releasably connected to each other by means of screws ( 20 ) which are screwed into holes ( 9 ) provided with threads ( 16 ) in the cylinder head ( 29 , 33 ). The side of the cylinder head lower part ( 33 ) facing the cylinder ( 1 ) has a bottom ( 34 ) in which a first passage ( 32 ) and a second passage ( 5 ) are arranged. The first passage ( 32 ) forms with a resiliently designed, as valve closing member ( 4 ) serving gene part, which is clamped at one end between the cylinder ( 1 ) and the cylinder head lower part ( 33 ), a suction valve ( 32 , 4 ), via which the compression chamber ( 3 ) can be connected to a suction chamber ( 31 , 25 ) arranged in the cylinder head ( 33 , 29 ). The second passage ( 5 ) forms with a resiliently designed, as a valve closing member ( 7 ) serving part, which is attached to the bottom of the cylinder head, a pressure valve ( 5 , 7 ), through which the compression chamber ( 3 ) with a in der Zylin derkopf arranged pressure chamber ( 10 , 17 ) can be connected. The valve closing member ( 7 ) of the pressure valve ( 5 , 7 ) is located in the pressure chamber ( 10 , 17 ). The opening stroke of the valve closing member ( 7 ) of the pressure valve ( 5 , 7 ) is limited by a valve catcher ( 8 ) also arranged in the pressure chamber ( 10 , 17 ). The pressure chamber ( 10 , 17 ) and the suction chamber ( 31 , 25 ) are separated from one another by means of an arranged wall ( 21 ) in the cylinder head ( 33 , 29 ). The suction chamber ( 31 , 25 ) is on a on the cylinder head ( 33 , 29 ) arranged suction port ( 71 ) with the atmosphere in connec tion and the pressure chamber ( 10 , 17 ) is arranged on a cylinder head ( 33 , 29 ) pressure port ( 18 ) connected to a consumer.

In the pressure chamber ( 10 , 17 ) and the suction chamber ( 31 , 25 ) surrounding or delimiting walls of the Zylinderkop fes ( 33 , 29 ), such as. B. jacket of the cylinder head ( 33 , 29 ) and wall ( 21 ), are formed as channels Kühlmit telraums ( 30 , 30 ', 24 ) arranged with each other and via a coolant connection ( 15 ) with a coolant source for gaseous or liquid coolant are connected.

The coolant spaces ( 30 and 30 ') are formed as a coherent, in the jacket of the cylinder head ( 29 , 30 ) angeord designated channel.

Between the cylinder head upper part ( 29 ) facing end face ( 11 ) of the cylinder head lower part ( 33 ) and the cylinder head lower part ( 33 ) facing end face ( 13 ) of the cylinder head upper part ( 29 ), a flat sealing device ( 72 ) is clamped. The flat seal ( 72 ) has in the area of the pressure chamber ( 10 , 17 ), the suction chamber ( 25 , 31 ) and the coolant chambers ( 30 , 24 , 30 ') these spaces freige bende recesses.

On its side facing the cylinder head upper part ( 29 ), the wall of the cylinder head lower part ( 33 ) delimiting the pressure chamber ( 10 , 17 ) has a circumferential shoulder ( 73 ) and a plurality of ribs ( 74 , 75 ) which are flush with the shoulder ( 73 ). trained projections. The ribs ( 74 , 75 ) extend in the direction of the longitudinal axis of the cylinder head ( 29 , 33 ) and extend transversely to the longitudinal axis of the cylinder head ( 29 , 33 ) into the pressure chamber ( 10 , 17 ). On the shoulder ( 73 ) and the cylinder head upper part ( 29 ) facing the end with the set from ( 73 ) closing ribs ( 74 , 75 ) is a wall-like part formed by a plate ( 76 ). The thickness of the plate (76) is selected such that it with the cylinder head upper part (29) facing end surface is flush with its side facing the cylinder head upper part (29) side facing flush (11) of the cylinder head lower part (33) or slightly above this end face (11) protrudes. Be due to the paragraph ( 73 ) and the diameter of the pressure chamber ( 10 , 17 ) larger outside diameter of the plate ( 76 ), the edge region of the plate ( 76 ) is covered by part of the flat gasket ( 72 ). In this way, the plate ( 76 ) after the connection of the cylinder head lower part ( 33 ) and the cylinder head upper part ( 29 ) to each other under prestress from the flat gasket ( 72 ) on the shoulder ( 73 ) which limits the pressure space ( 10 , 17 ) the wall of the cylinder head lower part ( 33 ) held. The plate ( 76 ) is arranged transversely to the longitudinal axis of the cylinder head ( 29 , 33 ) in the pressure chamber ( 10 , 17 ) so that the pressure chamber ( 10 , 17 ) in a in the Zylinderkopfun lower part ( 33 ) located pressure valve-side first Druckkam mer ( 10 ) and a pressure connection-side second pressure chamber ( 17 ) located in the cylinder head upper part ( 29 ).

Similarly, the suction space ( 31 , 25 ) is provided by a wall-like part arranged transversely to the longitudinal axis of the cylinder head ( 29 , 33 ) and formed by a cup-shaped part ( 79 , 80 ) in the suction space ( 31 , 25 ). into a suction port-side first suction chamber ( 25 ) located in the cylinder head upper part ( 29 ) and a suction valve-side second suction chamber ( 31 ) in the cylinder head lower part ( 33 ). The cup-shaped part ( 79 , 80 ) has a bottom ( 79 ) and a jacket ( 80 ). It is arranged in the suction chamber ( 31 , 25 ) in such a way that the outer edge region of its bottom ( 79 ) rests on the end face of ribs ( 81 , 82 ) facing the cylinder head upper part ( 29 ), which ribs ( 81 , 82 ) extend in the direction of the longitudinal axis of the cylinder head 29, 33) extending at the suction space (25, 31) delimiting wall of the Zylinderkopfuntertei les (33) and extending transversely of a stretch in the suction chamber (25, 31) towards the longitudinal axis of the cylinder head (29, 33). The outer surface of the jacket ( 80 ) of the pot-shaped part ( 79 , 80 ) lies against the wall of the cylinder head lower part ( 33 ) delimiting the suction space ( 25 , 31 ). The end face of the jacket ( 80 ) of the cup-shaped part ( 79 , 80 ) facing away from the bottom ( 79 ) extends towards the cylinder head upper part ( 29 ), with the end face ( 11 ) of the cylinder head lower part ( 33 ) facing the cylinder head upper part ( 29 ). is flush or protrudes slightly beyond this end face ( 11 ). The flat seal ( 72 ) is designed in the area of the suction space ( 25 , 31 ) so that it protrudes a little into it and covers the end of the shell ( 80 ) of the cup-shaped part ( 79 , 80 ) facing it. In this way, the cup-shaped part ( 79 , 80 ) after connecting the cylinder head lower part ( 33 ) and cylinder head upper part ( 29 ) with each other under tension from the flat gasket ( 72 ) on the end face of the ribs ( 81 , 82 ).

Via a first passage opening ( 77 ) provided in the plate ( 76 ), the first pressure chamber ( 10 ) is continuously connected to the second pressure chamber ( 17 ). Likewise, the first suction chamber ( 25 ) via a in the bottom ( 79 ) of the cup-shaped part ( 79 , 80 ) arranged second passage opening ( 78 ) is continuously connected to the second suction chamber ( 31 ).

In Fig. 2 is a plan view of the cylinder head of the compressor according to FIG. 1 with the cylinder head part removed. For the sake of a better overview, the components that are the same as the components shown in FIG. 1 are provided with the same reference numbers.

The lower part of the cylinder head has the first pressure chamber ( 10 ) and the second suction chamber ( 31 ) as well as the first coolant spaces ( 30 , 30 ') designed as channels. The first pressure chamber ( 10 ) is covered by the plate ( 76 ) which rests on the ribs ( 73 , 73 ', 75 , 75 ', 75 "). As can be clearly seen in the drawing, the plate ( 76 ) arranged through opening ( 77 ) for connecting the first pressure chamber ( 10 ) to the second pressure chamber of the pressure chamber has a relatively small passage cross-section, so that the greater part of the most pressure chamber ( 10 ) of the pressure chamber is covered by the plate ( 76 ). in the bottom (34) of the cylinder head lower part (33) the passage opening (5) and the valve stop (8) of the pressure valve (5, 7) shown in dotted lines. the also located in the cylinder head lower part second suction chamber (31) of the suction space, of the on the ribs ( 81 , 82 ) mounted cup-shaped part ( 97 , 80 ) is covered, is in the testicle ( 79 ) of the cup-shaped Tei les ( 79 , 80 ) arranged through opening ( 78 ) with the located in the cylinder head top first suction chamber connected. The through opening ( 78 ) in the pot-shaped part ( 79 , 80 ) has a much larger passage cross section than the through opening ( 77 ) in the plate ( 76 ). So that no suction losses or throttling losses occur, the cross section of the through opening ( 78 ) of the cup-shaped part ( 79 , 80 ) must be at least as large or even larger than the through cross section of the suction connection.

The bottom ( 34 ) of the cylinder head lower part ( 33 ) has a plurality of through openings ( 32 , 38 ) which, together with the tongue-like valve closing member ( 4 ), form the suction valve ( 32 , 38 , 4 ). In the jacket of the cylinder head ( 33 ) of the pressure chamber and the suction chamber partially surrounding, designed as a channel first coolant chamber ( 30 , 30 ') is arranged, which is connected to the coolant source via the coolant connection ( 36 ). Designed as a coolant channel, arranged in the wall ( 21 ) of the cylinder head further coolant chamber ( 24 ) is connected to the coolant chamber ( 30 , 30 ') arranged in the jacket of the cylinder head, so that these two coolant chambers ( 30 , 30 ', 24 ) the pressure chamber and the suction chamber practically ring-shaped.

The view of the cylinder head shown in FIG. 1 is a section through the cylinder head according to section line AA in FIG. 2.

The function of the one shown in the above figures ten wall-like parts are explained in more detail below.

During a suction stroke of the piston ( 2 ) of the compressor, the suction valve ( 32 , 4 ) opens and air is drawn into the compression chamber ( 3 ). The air flows from the suction connection into the first suction chamber ( 25 ), is distributed in this, wherein it acts on the first suction chamber ( 25 ) delimiting pot-shaped part ( 79 , 80 ). From the first Saugkam mer ( 25 ), the air passes through the through opening ( 78 ) of the cup-shaped part ( 79 , 80 ) into the second suction chamber ( 31 ), in which it is in turn distributed and also the second suction chamber ( 31 ) limit the area of the pot-shaped part ( 79 , 80 ). The air then enters the compression chamber ( 3 ) through the opened suction valve ( 32 , 4 ).

During the subsequent compression stroke of the piston ( 2 ), the suction valve ( 32 , 4 ) closes and the pressure valve ( 5 , 7 ) reaches its open position. The compressed air passes through the open pressure valve ( 5 , 7 ) into the pressure chamber ( 10 ) and acts on the area of the plate ( 76 ) delimiting the first pressure chamber ( 10 ). The incident on the plate (76) compressed air stream is deflected by the plate (76) and passes through the opening in the region of the pressure chamber (10, 17) arranged in the passage (77) in the plate (76) in the second pressure chamber (17). As in the first pressure chamber ( 10 ), the compressed air is distributed in the second pressure chamber ( 17 ) and then passes to the pressure connection ( 18 ) through which it emerges and via an unillustrated connection to the pressure connection ( 18 ) to a pressure medium line Consumer arrives.

Since the compressed air in the first pressure chamber (10), conditionally opening through the formed as a separator plate (76) and the relatively small passage cross section of the passage (77), a determined by the size of the Durchlaßquer-section of the passage opening (77) dwell time in the has first pressure chamber ( 10 ), the heat generated by the compressed air is dissipated well via the plate ( 76 ).

The arrangement of the serving as separating elements wan-like parts ( 76 , 79 , 80 ) in the cylinder head, which is probably in the area of the pressure chamber ( 10 , 17 ) and in the loading area of the suction chamber ( 31 , 25 ) or in the area other Additional spaces (e.g. in the case of a compressor with self-stabilization) have through openings ( 77 , 78 ), forced guidance of the intake air and the compressed air can be specified. The compressed air in the pressure chamber ( 10 , 17 ) can be directed to well-cooled areas in the cylinder head ( 33 , 29 ).

If the plate ( 76 ) serving as a separating element is connected to the valve catcher ( 8 ) for the pressure valve ( 5 , 7 ) via a connecting element, the heat dissipation can be improved still further.

By arranging at least one of the described wall-like parts in the cylinder head becomes the pressure port temperature of the compressor compared to the known Ver more densely reduced.

In Fig. 3, the cylinder head of a compressor is Darge, which has substantially the same structure as the cylinder head shown in Fig. 1, but the cylinder head upper part is transverse to the longitudinal axis of the cylinder head and divided between the facing end faces of the two parts of the cylinder head upper part, a second seal is arranged. Furthermore, a further wall-like part serving as a separating element is arranged in the pressure chamber and in the suction chamber of the compressor, running transversely to the longitudinal axis of the cylinder head. For the sake of a better overview, the components corresponding to the components shown in FIG. 1 are provided with the same reference numbers. The components that are the same as the components shown in FIG. 1 and already described are only explained as far as is necessary to understand FIG. 3.

The upper part of the cylinder head is subdivided into a lower part ( 33 ) of the lower part of the cylinder head ( 29 a) and a second upper part ( 29 b) connected to the upper part of the cylinder head. The two cylinder head parts ( 29 a and 29 b) are connected to each other and to the cylinder head lower part ( 33 ) by means of screws ( 20 ). Between the second cylinder head upper part ( 29 b) facing end face ( 63 ) of the first cylinder head upper part ( 29 a) and the first cylinder head upper part ( 29 a) facing end face ( 65 ) of the second cylinder head top part ( 29 b) is a second flat gasket ( 83 ) clamped. The second flat seal ( 83 ) has in the area of the pressure chamber, the suction chamber and the cooling agent telraums ( 30 , 24 , 30 ') these spaces releasing recesses.

On its side facing the second cylinder head upper part ( 29 b), the wall of the first cylinder head upper part ( 29 a) delimiting the second pressure chamber ( 17 ) of the pressure chamber ( 10 , 17 ) has a circumferential shoulder ( 85 ) and several with the shoulder ( 85 ) on flush projections designed as ribs ( 86 , 87 ). The ribs ( 86 , 87 ) extend in the direction of the longitudinal axis of the cylinder head ( 29 , 33 ) and extend transversely to the longitudinal axis of the cylinder head ( 29 , 33 ) into the pressure chamber. On the shoulder ( 85 ) and the top of the second cylinder head part ( 29 b) facing the end with the set ( 85 ) closing ribs ( 86 , 87 ) is a wall-like part formed by a further plate ( 84 ). The thickness of the plate (84) is selected so that it with its the second cylinder head upper part-facing side (29 b) flush cap with the second cylinder head facing end surface (63) (29 b) of the first cylinder head upper part (29 a) closes or protrudes somewhat beyond this end face ( 63 ). Due to the rate ( 85 ) and the larger outside diameter of the plate ( 84 ) compared to the diameter of the pressure chamber ( 10 , 17 ), the edge region of the plate ( 84 ) is covered by part of the second flat seal ( 83 ). In this way, the plate ( 84 ) after connecting the first cylinder head part ( 29 a) and the second cylinder head part ( 29 b) with each other under tension from the flat gasket ( 83 ) on the shoulder ( 85 ) of the pressure chamber ( 10 , 17 ) boundary wall of the first cylinder head upper part ( 29 a) held. The further plate ( 84 ) divides the second pressure chamber ( 17 ) of the pressure chamber ( 10 , 17 ) into a first partial chamber ( 17 a) and a second partial chamber ( 17 b), the first partial chamber ( 17 a) being separated from the plate ( 76 ) and the further plate ( 84 ) and the second partial chamber ( 17 b) of the further plate ( 84 ) and the second cylinder head part ( 29 b) is limited. In the same way, the first suction chamber ( 25 ) of the suction chamber ( 25 , 31 ) is formed by a further cup-shaped part ( 90 , 88 ), which forms a wall-like part, into a first partial chamber ( 25 a) and a second partial chamber ( 25 b) divided, the first partial chamber ( 25 a) from the cup-shaped part ( 79 , 80 ) and the further cup-shaped part ( 90 , 88 ) and the second partial chamber ( 25 b) from the further cup-shaped part ( 90 , 88 ) and the second cylinder head upper part ( 29 b) is limited.

The further cup-shaped part ( 90 , 88 ) has a bottom ( 90 ) and a jacket ( 88 ). It is arranged in the suction chamber ( 25 , 31 ) in such a way that it rests with the outer edge region of its base ( 80 ) on the end face of ribs ( 89 , 92 ) facing the second cylinder head part ( 29 b), which is in the direction of the longitudinal axis of the cylinder head ( 29 , 33 ) extending on the wall of the first cylinder head upper part ( 29 a) delimiting the suction chamber and extending transversely to the longitudinal axis of the cylinder head ( 29 , 33 ) into the suction chamber ( 25 , 31 ).

The jacket ( 88 ) of the further cup-shaped part ( 90 , 88 ) lies with its outer surface against the wall of the first cylinder head upper part ( 29 a) limiting the suction space. The end face of the jacket ( 88 ) facing away from the bottom ( 90 ) of the further cup-shaped part ( 90 , 88 ) extends to the second cylinder head upper part ( 29 b), whereby it faces the end face ( 63 ) with the second cylinder head upper part ( 29 b) ) of the first cylinder head upper part ( 29 a) ends flush or protrudes somewhat beyond this end face ( 63 ). The flat gasket ( 83 ) is formed in the area of the suction chamber ( 25 , 31 ) so that it protrudes a bit into it and covers the end face of the jacket ( 88 ) of the cup-shaped part ( 90 , 88 ) facing it. In this way, the cup-shaped part ( 90 , 88 ) after connecting the first cylinder head part ( 29 a) and the second cylinder head part ( 29 b) with each other under tension from the flat gasket ( 83 ) on the end face of the ribs ( 89 , 92 ) held.

Via a through opening ( 93 ) provided in the further plate ( 84 ), the first sub-chamber ( 17 a) of the pressure chamber ( 10 , 17 ) is continuously connected to the second sub-chamber ( 17 b) of the pressure chamber ( 10 , 17 ). Likewise, the first sub-chamber ( 25 a) of the suction chamber ( 25 , 31 ) is continuously connected to the second sub-chamber ( 25 b) of the suction chamber ( 25 ) through a through-opening ( 91 ) arranged in the bottom ( 90 ) of the further cup-shaped part ( 90 , 88 ). 25 , 31 ) connected. The passage opening ( 77 ) located in the pressure chamber ( 10 , 17 ) in the plate ( 76 ) and the passage opening ( 93 ) located in the pressure chamber ( 10 , 17 ) in the further plate ( 84 ) are offset from one another. Likewise in the suction chamber (31, 25) located through opening (78) in the cup-shaped part (79, 80) and in the suction space (31, 25) through opening (91) located offset in the other cup-shaped part (88, 90) arranged to each other.

During a suction stroke of the piston ( 2 ) of the compressor, air enters the partial chamber ( 25 b) of the first suction chamber ( 25 ) from the suction connection, from there through the through opening ( 91 ) in the pot-shaped part ( 88 , 90 ) into the partial chamber ( 25 a ) of the first suction chamber (25) and from this through the cup-shaped part (79, 80) arranged Durchgangsöff voltage (78) in the second suction chamber (31) of the suction chamber (31, 25), from which it through the opened suction valve (32 , 4 ) in the compression chamber ( 3 ) of the compressor. During the subsequent compression stroke of the piston ( 2 ) of the compressor, the compressed air flows through the pressure valve ( 5 , 7 ) into the first pressure chamber ( 10 ), passes from the latter through the passage opening ( 77 ) arranged in the plate ( 76 ) into the first sub-chamber ( 17 a) and from this further through the through-hole ( 93 ) arranged in the further plate ( 84 ) into the second sub-chamber ( 17 b) of the pressure chamber ( 10 , 17 ), from which it passes through the pressure connection ( 18 ) gets into a pressure line connected to a consumer.

It is of course also possible to use the cylinder head lower part divided across the longitudinal axis of the cylinder head train and then between the two cylinder heads divide an additional plate or an additional one  to arrange pot-shaped part, which or which in Cylinder head lower part of the pressure chamber or suction chamber always divided into subchambers, which are then in this Plate or arranged in this pot-shaped part Through openings are interconnected.

In Fig. 4, a compressor is shown, in which the wall-like part serving as a separating element is formed by a seal designed in a special way, which is arranged between the cylinder head lower part and the cylinder head upper part. The arrangement of a plate or a pot-shaped part in the pressure chamber or in the suction chamber of the cylinder head is then no longer necessary.

Since the compressor shown in FIG. 4 has essentially the same structure as the compressor shown in FIG. 1, the same reference numbers are used for the same components for the sake of a better overview.

According to Fig. 4 of a compressor for generating compressed air, a piston (2) in the direction of the longitudinal axis of the cylinder (1) is movably arranged in a cylinder (1). The Zy cylinder ( 1 ) has a compression chamber ( 3 ) which is limited on the one hand by the piston ( 2 ) and on the other hand by a cylinder head ( 33 , 29 ). The cylinder ( 1 ) and the cylinder head Zy ( 33 , 29 ) are means not shown, such as. B. screws or studs mitein connected, wherein a cylinder head gasket ( 6 ) is arranged between the facing sides of the cylinder head ( 33 , 29 ) and cylinder ( 1 ).

The cylinder head ( 33 , 29 ) is formed transversely to the longitudinal axis of the cylinder ( 1 ) divided so that it consists of a Zy cylinder head lower part ( 33 ) and a cylinder head cover serving as the cylinder head upper part ( 29 ). The Zylin derkopfoberteil ( 29 ) and the cylinder head lower part ( 33 ) are releasably connected to each other by means of screws ( 20 ) which are screwed into holes ( 9 ) provided with threads ( 16 ) in the cylinder head ( 29 , 33 ). The side of the cylinder head lower part ( 33 ) facing the cylinder ( 1 ) has a bottom ( 34 ) in which a first passage ( 32 ) and a second passage ( 5 ) are arranged. The first passage ( 32 ) forms with a resiliently designed, as valve closing member ( 4 ) serving gene part, which is clamped at one end between the cylinder ( 1 ) and the cylinder head lower part ( 33 ), a suction valve ( 32 , 4 ), via which the compression chamber ( 3 ) can be connected to a suction chamber ( 31 , 25 ) arranged in the cylinder head ( 33 , 29 ). The second passage ( 5 ) forms with a valve closing member ( 7 ) a pressure valve ( 5 , 7 ), via which the compression chamber ( 3 ) can be connected to a pressure chamber ( 10 , 17 ) arranged in the cylinder head. The valve closing member ( 7 ) of the Druckven valve ( 5 , 7 ) is located in the pressure chamber ( 10 , 17 ). The opening stroke of the valve closing member ( 7 ) of the pressure valve ( 5 , 7 ) is limited by a valve catcher ( 8 ) which is also arranged in the pressure chamber ( 10 , 17 ). The pressure chamber ( 10 , 17 ) and the suction chamber ( 31 , 25 ) are separated from one another by means of a wall ( 21 ) arranged in the cylinder head ( 33 , 29 ). The suction chamber (31, 25) is connected via a linder head on Zy (33, 29) arranged suction connection with the at phere in connection and the pressure chamber (10, 17) over a cylinder head (33, 29) arranged Druckan circuit (18) connected to a consumer.

In the pressure chamber ( 10 , 17 ) and the suction chamber ( 31 , 25 ) surrounding or delimiting walls of the Zylinderkop fes ( 33 , 29 ), such as. B. jacket of the cylinder head ( 33 , 29 ) and wall ( 21 ), are formed as channels Kühlmit telraums ( 30 , 27 , 24 , 22 , 30 ', 27 ') arranged un with each other and via a coolant connection ( 15 ) with a coolant source for gaseous or liquid coolant are connected. The coolant chamber ( 27 , 30 ) and the coolant chamber ( 27 ', 30 ') are designed as a coherent, in the jacket of the cylinder head ( 29 , 33 ) angeord designated channel.

Between the cylinder head upper part ( 29 ) facing end face ( 11 ) of the cylinder head lower part ( 33 ) and the cylinder head lower part ( 33 ) facing end face ( 13 ) of the cylinder head upper part ( 29 ) is designed as a plate-like seal ( 12 ) a wall-like part a stretched from a heat-dissipating material, such as B a metallic material. The plat-like seal ( 12 ) divides the pressure chamber ( 10 , 17 ) in a in the cylinder head lower part ( 33 ) located Druckven valve-side first pressure chamber ( 10 ) and in the cylinder head upper part ( 29 ) located pressure connection-side second pressure chamber ( 17 ). In the same way, the suction chamber ( 31 , 25 ) is divided by the plate-like seal ( 12 ) in a cylinder head upper part ( 29 ) located in the suction port side he ste suction chamber ( 25 ) and in the cylinder head lower part ( 33 ) located the suction valve-side second suction chamber ( 31 ).

Via a first passage opening ( 19 ) provided in the seal ( 12 ), the first pressure chamber ( 10 ) is continuously connected to the second pressure chamber ( 17 ). Likewise, the first suction chamber ( 25 ) is continuously connected to the second suction chamber ( 31 ) via a second through opening ( 26 ) arranged in the seal ( 12 ). Likewise, the coolant spaces from the plate-like seal ( 12 ) in the cylinder head lower part ( 33 ) located first Kühlmit telkammern ( 30 , 24 , 30 ') and in the cylinder head upper part ( 29 ) located second coolant chambers ( 27 ', 22 , 27 ) under, whereby the first coolant chamber ( 30 ) of the Kühlmit telraumes ( 30 , 27 ) via a in the seal ( 12 ) arranged through opening ( 28 ) with the associated second coolant chamber ( 27 ), the first coolant chamber ( 24 ) of the coolant chamber ( 24 , 22nd ) via an disposed in the log device (12) through opening (23) with its associated second coolant chamber (22) and the first coolant chamber (30 '(30) of the coolant chamber', 27 ') via a disposed in the seal (12) Durchgangsöff opening ( 14 ) with its associated second Kühlmittelkam mer ( 27 ') is connected.

In Fig. 5 is a plan view of the cylinder head of the compressor of FIG. Berteil shown with removed Zylinderkopfo. 4 For the sake of a better overview, the components that are the same as the components shown in FIG. 4 are provided with the same reference numbers.

The cylinder head lower part, the first pressure chamber (10) and the second suction chamber (31) and which are formed as channels first coolant chambers (30; 24, 30 ') on. As can be clearly seen in the drawing, the passage opening ( 19 ) arranged in the plate-like seal ( 12 ) for connecting the first pressure chamber ( 10 ) to the second pressure chamber of the pressure chamber has a relatively small passage cross section, so that the greater part of the first pressure chamber ( 10 ) of the pressure chamber is covered by the plate-like seal ( 12 ). In the bottom ( 34 ) of the cylinder head lower part ( 33 ), the through opening ( 5 ) and the Ven tilfänger ( 8 ) of the pressure valve ( 5 , 7 ) are shown in dashed lines Darge. The second suction chamber ( 31 ) of the suction chamber, which is also located in the lower part of the cylinder head, is connected via the passage opening ( 26 ) arranged in the seal ( 12 ) to the first suction chamber located in the upper part of the cylinder head. The passage opening ( 26 ) has a much larger passage cross section than the passage opening in the pressure chamber. So that no suction losses or throttling losses occur, the cross section of the through opening ( 26 ) must be at least as large or even larger than the through cross section of the suction connection.

The bottom ( 34 ) of the cylinder head lower part ( 33 ) has a plurality of through openings ( 32 , 38 ) which, together with the tongue-like valve closing member ( 4 ), form the suction valve ( 32 , 38 , 4 ). In the jacket of the cylinder head ( 33 ) of the pressure chamber and the suction chamber partially surrounding, designed as a channel first coolant chamber is arranged, which is divided by the plate-shaped seal ( 12 ) un. The seal ( 12 ) divides the channel into the second coolant chamber located in the upper part of the cylinder head and the coolant chamber ( 30 , 30 ') located in the lower part of the cylinder head ( 33 ). The second coolant chamber and the first coolant chamber ( 30 , 30 ') of the coolant channel are arranged in the seal ( 12 ) through openings ( 28 , 35 , 44 , 45 , 43 , 14 and 40 ) with each other and with the in Connected coolant connection ( 36 ) connected to the coolant source. The passage ( 42 ) arranged in the seal ( 12 ) serves to connect the second coolant chamber arranged in the cylinder head upper part to the first coolant chamber located in the cylinder head lower part ( 33 ). A designed as a coolant channel, arranged in the wall ( 21 ) of the cylinder head further coolant chamber is connected to the coolant chamber arranged in the jacket of the cylinder head, so that these two coolant spaces surround the pressure chamber and the suction chamber practically ring-shaped. The coolant channel designed as a coolant channel is divided into the coolant chamber ( 24 ) located in the cylinder head lower part ( 33 ) and the coolant chamber located in the cylinder head upper part. The two coolant chambers of the further Kühlmittelrau mes ( 24 , 22 ) are in the seal ( 12 ) arranged through openings ( 39 and 48 ) constantly connected to each other. Through further, in the seal ( 12 ) arranged through openings ( 37 , 41 , 47 and 46 ), the cylinder head ( 29 , 33 ) with the cylinder ( 1 ) connecting, not shown screws are passed.

The view of the cylinder head shown in FIG. 4 is a section through the cylinder head according to section line AA in FIG. 5.

In Fig. 6 is a view of the above-described cylinder head along the section line BB of FIG. 5 is shown. For the sake of a better overview, the components that are the same as the components shown in FIGS . 4 and 5 are provided with the same reference numbers.

As can be seen from Fig. 6 and described above, the pressure valve consists of a in the bottom ( 34 ) of the cylinder head lower part ( 33 ) arranged through passage ( 5 ) and a plate-like valve closing member ( 7 ), which on the compression chamber ( 3 ) Abge facing side of the bottom ( 34 ) rests on this and covers the through hole ( 5 ). The valve closing member ( 7 ) is held by a preloaded leaf spring ( 51 ) on the Bo ( 34 ). The leaf spring ( 51 ) is held at its ends by means of screws ( 49 and 50 ) on the bottom ( 34 ) of the cylinder head lower part ( 34 ). The same screws ben fix the arcuate valve catcher ( 8 ) with its ends on the floor ( 34 ). Of the leaf spring (51) and the valve closure member (7) arcuately spans the valve stop (8) of the pressure valve (5, 7) is associated, limits the stroke of the valve closure member (7) in the opening direction of the pressure valve (5, 7).

The through opening ( 19 ) in the area of the plate-like seal ( 12 ) which divides the pressure chamber ( 10 , 17 ) into a first first pressure chamber ( 10 ) and a second pressure chamber ( 17 ) is laterally offset from the pressure valve ( 5 , 7 ). so that the pressure valve ( 5 , 7 ) emerging compressed air can not get directly from the first pressure chamber ( 10 ) into the second pressure chamber ( 17 ), but from the element serving as a separating element seal ( 12 ) only in the direction must be redirected to the through opening ( 19 ).

Clearly seen in Fig. 6, the passage opening (40) and the passage opening (44) in the loading area of the seal (12) surrounding the head in the shell of the cylinder (29, 33) arranged and designed as a channel coolant space (27 ', 27; 30', 30) in the location in Zylinderkop funterteil (33) first coolant chamber (30 ', 30) (27, 27) and located in the cylinder head upper part (29) second coolant chamber divided.

In Fig. 7 a section of the top view of the cylinder head according to FIG. 4 is shown with the cylinder head removed, but the seal in the area of the suction head of the cylinder head is a different design from that shown in FIG. 1 or in FIG. 5 having.

The cylinder head has the plate-like seal ( 12 ) which is substantially the same as the seal shown in Figs. 4-6. Also in this figure, the components and through-openings shown in FIGS . 4-6 as well as rooms with the same components, through-openings and spaces are provided with the same reference numbers.

In contrast to the seal shown in FIG. 5, the area dividing the suction space ( 31 , 25 ) into a first suction chamber and a second suction chamber of the plate-like seal ( 12 ) designed as a separating element does not have a single larger through opening, but rather a plurality of slots ( 52 ) or a plurality of small circular or oval through openings ( 53 ) for connecting the ge in the cylinder head lower part ( 33 ) ge second suction chamber ( 31 ) with the upper part in the cylinder head ( 29 ) located on the first suction chamber ( 25 ).

The formation of the passages in the pressure chamber ( 10 ) and the coolant chambers in first and second chambers un dividing areas of the plate-like seal ( 12 ) is also in the device shown in Fig. 7 device as in the seal shown in Fig. 5 .

The function of the one shown in the above figures th seal is explained in more detail below.

During a suction stroke of the piston ( 2 ) of the compressor, the suction valve ( 32 , 4 ) opens and air is drawn into the compression chamber ( 3 ). The air flows from the suction connection into the first suction chamber ( 25 ), is distributed therein, and acts on the area of the seal ( 12 ) delimiting the first suction chamber ( 25 ). The air then passes from the first suction chamber ( 25 ) through the passage opening ( 26 ) in the seal ( 12 ) into the second suction chamber ( 31 ), in which it is distributed and thereby also the region of the second suction chamber ( 31 ) Seal ( 12 ) applied. The air then enters the compression chamber ( 3 ) through the opened suction valve ( 32 , 4 ).

During the subsequent compression stroke of the piston ( 2 ), the suction valve ( 32 , 4 ) closes and the pressure valve ( 5 , 7 ) reaches its open position. The compressed air passes through the open pressure valve ( 5 , 7 ) into the pressure chamber ( 10 ) and acts on the area of the seal ( 12 ) which delimits the first pressure chamber ( 10 ). The impinging on the seal (12) compressed air stream is deflected by the seal (12) and passes through in the region of the pressure chamber (10, 17) arranged through-opening (19) in the seal (12) in the second pressure chamber (17). As in the first pressure chamber ( 10 ), the compressed air is distributed in the second pressure chamber ( 17 ) and then reaches the pressure connection ( 18 ), through which it emerges and via a pressure medium line (not shown) connected to the pressure connection ( 18 ) Consumer arrives.

Since the compressed air in the first pressure chamber ( 10 ), due to the seal designed as a separating element ( 12 ) and the relatively small passage cross-section of the passage opening ( 19 ), a through the size of the passage cross section of the passage opening ( 19 ) determined dwelling in the has first pressure chamber ( 10 ), the heat generated by the compressed air is derived via the device ( 12 ) well.

Since the seal ( 12 ) not only into the pressure chamber ( 10 , 17 ), but also into the suction chamber ( 31 , 25 ) and into the coolant chambers ( 30 , 30 '; 27 , 27 '; and 24 , 22 ) stretches, the heat is advantageously derived in addition to the coolant and to the ge of the sucked-in area of the seal ( 12 ).

By forming the between the cylinder head upper part ( 29 ) and lower cylinder head part ( 33 ) arranged seal ( 12 ) as a plate-like separating element, which both in the area of the pressure chamber ( 10 , 17 ) and in the area of the suction chamber ( 31 , 25 ) and in the areas of Coolant spaces ( 30 , 30 '; 27 , 27 '; 24 , 22 ) or other additional spaces (e.g. in the case of a compressor with self-stabilization) through openings ( 28 , 35 , 40 , 14 , 43 , 44 , 45 , 48 , 39 ), a forced guidance of the intake air, the compressed air and also the cooling can be predetermined by means of. The compressed air in the pressure chamber ( 10 , 17 ) can be directed to well-cooled points in the cylinder head ( 33 , 29 ).

If the seal ( 12 ) is connected to the valve catcher ( 8 ) for the pressure valve ( 5 , 7 ) via a connecting element, the heat dissipation can be improved still further.

By arranging the seal described in the Zylin the head becomes the pressure port temperature of the compressor significantly reduced compared to the known compressor.

If the compressor has a suction port on the side of the cylinder head, an additional rib is arranged on the seal, as shown in FIG. 5.

In Fig. 8 the same view of the cylinder head is shown as in Fig. 6. Since the cylinder head shown in Fig. 8 has substantially the same structure as the cylinder head shown in Figs. 4 and 6, those are in the components same construction as shown Figs. 4 and 6 share the same reference numerals provided. Since the cylinder head has already been described in detail above, only the modified embodiment of the seal arranged between the cylinder head lower part and the cylinder head upper part will be discussed below.

In the compressor according to FIG. 8, the suction connection ( 54 ) is arranged laterally on the lower part of the cylinder head ( 33 ). The between the cylinder head lower part ( 33 ) and upper cylinder head part ( 29 ) clamped seal ( 12 ) divides the pressure chamber ( 10 , 17 ) into the first pressure chamber ( 10 ) and the second pressure chamber ( 17 ), the suction chamber into the first suction chamber and the second Suction chamber and the coolant spaces ( 27 , 30 , 27 ', 30 ') in first coolant chambers ( 30 , 30 ') and second coolant chambers ( 27 , 27 '). The first passage opening ( 19 ) arranged in the plate-like seal ( 12 ) serves to connect the first pressure chamber ( 10 ) to the second pressure chamber ( 17 ).

The seal ( 12 ) has a rib-like part ( 56 ) which extends transversely to the longitudinal axis of the seal ( 12 ) ver running away from the seal ( 12 ) towards the bottom ( 34 ) of the cylinder head lower part ( 33 ). The free end of the rib-like member (56) is abgewin Celtic, wherein the angled portion by means of the catcher (8) of the pressure valve (5, 7) holding the screw (50) is connected to the pressure valve (5, 7) the valve.

The rib-like part ( 56 ) is arranged on the seal ( 12 ) such that it is located between the pressure valve ( 5 , 7 ) and the pressure connection ( 54 ) and together with the seal ( 12 ) the first pressure chamber ( 10 ) from one third pressure chamber ( 60 ) separates, which is continuously connected to the second pressure chamber ( 17 ) via a device in the device ( 12 ) arranged through hole ( 55 ).

This design and arrangement of the seal ( 12 ) is diverted during a delivery stroke of the piston ( 2 ) from the compression chamber ( 3 ) through the pressure valve ( 5 , 7 ) into the pressure chamber ( 10 ) entering the pressure chamber ( 10 ) to the side of the pressure valve ( 5 , 7 ), the first through opening ( 19 ) in the seal ( 12 ) is placed in the second pressure chamber ( 17 ), here it is redirected by the seal ( 12 ) and the cylinder head upper part ( 29 ) and passes through the the seal ( 12 ) to an ordered further passage opening ( 55 ) in the third pressure chamber ( 60 ) of the pressure chamber ( 10 , 17 , 60 ), from which they chem through the pressure connection ( 54 ) and a pressure medium line, not shown, to egg flows to a consumer. The dwell time of the compressed air in the pressure chamber ( 10 , 17 , 60 ) is extended by the measure described above, so that in the interaction of the compressed air with the large areas of the seal ( 12 ) and the rib-like part ( 56 ) a good dissipation of the heat in the pressure chamber ( 10 , 17 , 60 ) to the Kühlmittelräu men ( 30 , 30 '; 27 , 27 ') and to the cylinder head jacket he is aimed.

Characterized in that the seal ( 12 ) via the rib-like part ( 56 ) with the valve catcher ( 8 ) of the pressure valve ( 5 , 7 ) is connected, also the pressure valve ( 5 , 7 ) particularly strongly occurring heat is dissipated well.

It is also possible, as shown in FIG. 9, not to provide a rib-like part on the seal, but rather a first rib-like part between the pressure valve ( 5 , 7 ) and the pressure connection ( 54 ) at the bottom ( 34 ) of the cylinder head lower part ( 33 ) ( 59 ) to be arranged, which extends from the bottom ( 34 ) in the direction of the plate-like seal ( 12 ) and extends with its free end to the seal ( 12 ) or with its free end on the seal ( 12 ) is present. A second rib-like part ( 57 ) is arranged on the top of the cylinder head ( 29 ) opposite the first rib-like part ( 59 ), the second rib-like part ( 57 ) facing away from the top of the cylinder head ( 29 ) in the direction of the plate-like seal ( 12 ). to he stretches and reaches with its free end to the seal ( 12 ) or with its free end to the device ( 12 ).

This measure divides the pressure chamber into the first pressure chamber ( 10 ), the second pressure chamber ( 17 ), the third pressure chamber ( 61 ) and a fourth pressure chamber ( 62 ). The first pressure chamber ( 10 ) is connected via the first passage opening ( 19 ) arranged in the seal ( 12 ) to the second pressure chamber ( 17 ), the second pressure chamber ( 17 ) is arranged via a second part ( 57 ) arranged in the second rib-like part Through opening ( 58 ) communicates with the third pressure chamber ( 61 ), and the third pressure chamber ( 61 ) is connected to the fourth pressure chamber ( 62 ) via a further through opening ( 55 ) arranged in the seal ( 12 ).

During a delivery stroke of the piston ( 2 ), the compressed air emerging from the compression chamber ( 3 ) through the pressure valve ( 5 , 7 ) passes through the first pressure chamber ( 10 ) to the second pressure chamber ( 17 ), from there to the third pressure chamber ( 61 ) and from the third pressure chamber ( 61 ) to the fourth pressure chamber ( 62 ), from which it reaches the pressure connection ( 54 ) which is connected to a consumer via a pressure medium line, not shown.

By repeatedly deflecting the compressed air in the pressure chamber ( 10 , 17 , 61 , 62 ), caused by the seal ( 12 ), the rib-like parts ( 57 and 59 ) and the arrangement of the through openings offset with respect to the pressure valve ( 5 , 7 ) ( 19 or 58 or 55 ) the residence time of the compressed air in the pressure chamber ( 10 , 17 , 61 , 62 ) is extended and in connection with the large areas of the seal ( 12 ) and the rib-like parts ( 57 and 59 ) a good derivation of the Heat achieved in the pressure chamber to the coolant chambers ( 30 , 30 ', 27 , 27 ') and to the cylinder head jacket.

The pressure connection or pressure port temperature on the compressor is considerably reduced with the seal designed according to the invention and arranged in the cylinder head compared to the pressure connection or pressure port temperature of known compressors. The arrangement of the through openings ( 19 , 58 , 55 , 23 , 14 , 28 ) in the seal ( 12 ) and in the rib-like parts ( 57 , 59 and 56 ) as well as the shape of these through holes and rib-like parts are of course not the embodiments shown in the drawing voltage bound.

The through openings can be limited, for example, by an edge of the seal ( 12 ) and a wall of the cylinder head.

In Fig. 10, the cylinder head of a compressor is Darge, which has substantially the same structure as the cylinder head shown in Fig. 4, but the cylinder head upper part is formed transverse to the longitudinal axis of the cylinder head and divided between the facing end faces of the two parts of the cylinder head upper part, a second seal is arranged. For the sake of a better overview, the components corresponding to the components shown in FIG. 4 are provided with the same reference numbers.

The upper part of the cylinder head is subdivided into a lower part ( 33 ) adjoining the lower part of the cylinder head ( 29 a) and a second upper part ( 29 b) connected to it. The two cylinder head parts ( 29 a and 29 b) are connected by screws ( 20 ) to each other and to the cylinder head lower part ( 33 ). Between the second cylinder head upper part (29 b) facing the end face (63) of the first cylinder head upper part (29 a) and (b 29) the first cylinder head upper part (29 a) facing the end face (65) of the second cylinder head upper part is a second plate-like being formed Seal ( 64 ) clamped, which is made of a heat-dissipating material such. B. a metallic material. The plate-like second seal ( 64 ) divides the second pressure chamber of the pressure chamber into a first partial chamber ( 17 a) and a second partial chamber ( 17 b), the first partial chamber ( 17 a) being separated from the first seal ( 12 ) and the second seal ( 64 ) is limited and the second partial chamber ( 17 b) is limited by the second seal ( 64 ) and the second cylinder head upper part ( 29 b). In the same way, the first suction chamber of the suction chamber is divided by the second plate-like seal ( 64 ) into a first partial chamber ( 25 a) and a second partial chamber ( 25 b), the first partial chamber ( 25 a) being separated from the first seal ( 12 ) and the second seal ( 64 ) is limited and the second sub-chamber ( 25 b) is limited by the second seal ( 64 ) and the second cylinder head part ( 29 b). About a device in the second you ( 64 ) provided through opening ( 67 ), the first sub-chamber ( 17 a) is constantly connected to the second sub-chamber ( 17 b) of the pressure chamber. Likewise, the first sub-chamber ( 25 a) via a second device ( 64 ) arranged in the second passage opening ( 69 ) is constantly connected to the second sub-chamber ( 25 b) of the suction chamber. The passage opening ( 19 ) in the pressure chamber ( 10 , 17 a, 17 b) in the first seal ( 12 ) and the passage opening ( 66 ) in the pressure chamber ( 10 , 17 a, 17 b) in the second seal ( 64 ) are arranged offset to each other. Likewise, the passage opening ( 28 ) placed in the suction chamber ( 31 , 25 a, 25 b) in the first seal ( 12 ) and the passage opening ( 69 ) in the suction chamber ( 31 , 25 , 25 b) in the second seal ( 64 ) staggered. The coolant chambers located in the upper part of the cylinder head are also divided by the second plate-like seal ( 64 ) into first partial chambers ( 27 a, 22 a, 27 'a) and second partial chambers ( 27 b, 22 b, 27 ' b), the first partial chamber ( 27 a) of the coolant chamber ( 27 a, 27 b) via a passage opening ( 70 ) arranged in the second seal ( 64 ) with the second partial chamber ( 27 b) assigned to it, the first partial chamber ( 22 a) of the coolant chamber ( 22 a , 22 b) via a through opening ( 68 ) arranged in the second seal ( 64 ) with the associated second partial chamber ( 22 b) and the first partial chamber ( 27 'a) of the coolant chamber ( 27 ' a, 27 'b) via a in the second seal ( 64 ) arranged through opening ( 66 ) is connected to the associated second partial chamber ( 27 'b).

As can be seen from the above, he is plate-like seal ( 12 ) between the cylinder head lower part ( 33 ) and the first part ( 29 a) of the Zylin derkopfoberteiles ( 29 a, 29 b) and the second seal ( 64 ) between the first part ( 29 a) and the second part ( 29 b) of the cylinder head upper part ( 29 a, 29 b) clamped. The passage openings ( 28 , 23 and 14 ) in the coolant chambers of the cylinder head ( 33 , 29 a, 29 b) in the first seal ( 12 ) and the passage openings ( 70 , 68 and 66 ) in these coolant rooms in the second seal ( 64 ) are each offset from one another.

During a suction stroke of the piston ( 2 ) of the compressor, air enters the partial chamber ( 25 b) from the suction connection, from there through the through-opening ( 69 ) in the second seal ( 64 ) into the partial chamber ( 25 a) and from this through the the first seal ( 12 ) arranged through opening ( 26 ) in the second suction chamber ( 31 ) of the suction chamber ( 31 , 25 a, 25 b), from which it through the opened suction valve ( 32 , 4 ) into the compression chamber ( 3 ) of the compressor got. In the subsequent compression stroke of the piston ( 2 ) of the compressor, the compressed air flows through the pressure valve ( 5 , 7 ) into the first pressure chamber ( 10 ), passes from this through the passage opening ( 19 ) arranged in the first seal ( 12 ) into the first partial chamber ( 17 a) and from this further through the through-opening ( 67 ) arranged in the second seal ( 64 ) into the second partial chamber ( 17 b) of the pressure chamber ( 10 , 17 a, 17 b), from which they pass through the Pressure connection ( 18 ) arrives in a pressure line connected to a consumer.

It is of course also possible to use the cylinder lower part of the head transverse to the longitudinal axis of the cylinder head divide train and then between the two cylinders lower parts of the head a second or additional plattenar to arrange gasket, which the in the cylinder head Lower suction chamber, pressure chamber and coolant chambers divided into sub-chambers, which are then in the This seal arranged through openings with each other are connected.

It is important for the invention that the pressure chamber and / or the suction room and / or other rooms, such as. B. Coolant rooms and additional rooms, the cylinder head through a serving as a partition wall-like part, such as. B. a plate-like or pot-shaped part or a Seal divided into at least two chambers be that over at least one each in the wall-like Partly arranged through opening constantly with each other are connected. The wall-like part should preferably from a heat-dissipating material, such as. B. one metallic material (e.g. aluminum, steel, etc.) be stand. The through located in the pressure chamber and in the suction chamber passage openings in the wall-like part should be and suction valve of the compressor can be arranged offset, to be able to divert a large amount of air or compressed air nen.

Are two essentially parallel and spaced apart other in the cylinder head, transverse to the longitudinal axis of the cylinder  Wall-like parts arranged upside down are provided the through openings in the first wall-like part arranged offset to the suction valve or the pressure valve. The through openings in the first are also the same wall-like part and the through openings in the white teren wall-like part staggered, so that the air or compressed air is practically a laby rinth is guided and so the heat over the large areas Chen the wall-like parts can be easily removed.

The arrangement of wall-like parts according to the invention can be used with both single and multi-cylinder Compressors are used.

In FIGS. 1-3 which are arranged in the pressure chamber wall-like parts of plates and is arranged in the suction chamber wall-like parts are shown as being pot-shaped parts forms. Of course, the wall-like parts for the pressure chamber and for the suction chamber can also have the same design - only plates or only pot-shaped parts for the suction chamber and pressure chamber. It is of course also possible to arrange a wall-like part only in the pressure chamber or only in the suction chamber of the compressor. The formation of the wall-like part is of course not tied to the embodiment shown in the drawing - plate or cup-shaped part. The wall-like part serving as a separating element can have any other shape.

The wall-like part can according to the invention both in The lower part of the cylinder head and the upper part of the cylinder head of the compressor may be arranged in the area between  Pressure connection or suction connection and separation point between Cylinder head upper part and lower part or between pressure valve or suction valve and separation point between upper part of the cylinder head and lower part of the cylinder head. The wall-like part is on one in all the cases mentioned Paragraph that limit the pressure chamber or the suction chamber the wall or / and the end faces from on the wall arranged ribs or other projections ge stores and is held by the seal on this.

Instead of the heel, the ribs or the projections can also one in the pressure chamber or in the suction chamber set socket as a bearing for the wall-like part serve, the wall-like part then on a forehead side of the socket.

The passage opening for connecting the pressure or suction chambers or subchambers with each other can be in the wandar term part or from the wall-like part and the wall delimiting the pressure chamber or the suction chamber be bordered.

Claims (19)

1. Compressor with a cylinder head consisting of a lower cylinder head part and an upper cylinder head part connected to it, with the following features:

• a) in the cylinder head ( 33 , 29 ), a suction chamber ( 31 , 25 ) and a pressure chamber ( 10 , 17 ) as well as a Saugven valve ( 32 , 4 ) and a pressure valve ( 5 , 7 ) are arranged, a compression chamber ( 3 ) the compressor via the suction valve ( 32 , 4 ) with the suction chamber ( 31 , 25 ) and via the pressure valve ( 5 , 7 ) with the pressure chamber ( 10 , 17 ) can be connected;
• b) the suction chamber ( 31 , 25 ) is connected to a suction connection of the compressor and the pressure chamber ( 10 , 17 ) is connected to a pressure connection ( 18 ) of the compressor;
• c) in the cylinder head ( 33 , 29 ) at least one wall-like part ( 76 , 79 , 80 , 12 ) transverse to the longitudinal axis of the cylinder head upper part ( 29 ) and the cylinder head lower part ( 33 ) is arranged so that it extends the pressure chamber ( 10 , 17 ) and / or the suction chamber ( 25 , 31 ) in a pressure valve-side first pressure chamber ( 10 ) and a pressure connection-side second pressure chamber ( 17 ) or the suction chamber ( 25 , 31 ) in a suction connection-side first suction chamber ( 25 ) and a suction valve-side second Suction chamber ( 31 ) divided, the first pressure chamber ( 10 ) and the second pressure chamber ( 17 ) via a through opening ( 77 , 12 ) arranged in the wall-like part ( 76 , 12 ) or delimited by the wall-like part ( 76 , 12 ) 19 ) or the first suction chamber ( 25 ) and the second suction chamber ( 31 ) with one another via a through opening ( 78 , 26 ) arranged in the wall-like part ( 79 , 80 , 12 ) or delimited by the wall-like part ( 76 , 12 ) are connected;

characterized by the following features:

• a) a seal ( 72 ) is arranged between the facing end faces of the cylinder head lower part ( 33 ) and cylinder head upper part ( 29 );
• b) the wall-like part ( 76 , 79 , 80 , 12 ) consists of a heat-dissipating material;
• c) the cylinder head ( 33 , 29 ) has in addition to the suction chamber ( 25 , 31 ) and the pressure chamber ( 10 , 17 ) at least one other chamber ( 27 , 30 , 24 , 22 , 27 ', 30 ') for a coolant ;
• d) the wall-like part ( 76 , 79 , 80 , 12 ) is designed such that it additionally extends into the further space ( 27 , 30 , 24 , 22 , 27 ', 30 ') and into a first chamber ( 30 , 30 ', 24 ) and a second chamber ( 27 , 27 ', 22 ) divided;
• e) the first chamber ( 30 , 24 , 30 ') and the second chamber ( 27 , 22 , 27 ') are arranged one in the wall-like part ( 76 , 79 , 80 , 12 ) and one of the wall-like part ( 76 , 79 , 80 , 12 ) limited through opening ( 28 , 23 , 14 , 40 , 44 ) interconnected.

2. Compressor according to claim 1, characterized by the following features:

• a) in the pressure chamber ( 10 , 17 ) and / or in the suction chamber ( 25 , 31 ) of the cylinder head ( 29 , 33 ) is a further wall-like part ( 84 , 90 , 88 ) arranged transversely to the longitudinal axis of the cylinder head ( 29 , 33 ) , through which the second pressure chamber ( 17 ) or the first pressure chamber ( 10 ) of the pressure chamber ( 10 , 17 ) in a first partial chamber ( 17 a) and a second partial chamber ( 17 b) or the second suction chamber ( 31 ) or first suction chamber ( 25 ) of the suction chamber ( 25 , 31 ) is divided into a first partial chamber ( 25 a) and a second partial chamber ( 25 b), and the first partial chamber ( 17 a) and the second partial chamber ( 17 b) of the Pressure chamber ( 10 , 17 ) or the first sub-chamber ( 25 a) and the second sub-chamber ( 25 b) of the suction chamber ( 25 , 31 ) via one in the further wall-like part ( 84 ) or the further wall-like part ( 90 , 88 ) through opening ( 93 ) or through opening ( 91. ) Arranged or delimited by the further wall-like part ( 84 , 90 , 88 ) ) are connected.

3. Compressor according to claim 1 or claim 2, characterized in that the wall-like part is designed as a plate ( 76 , 84 ) which on a shoulder ( 73 , 85 ) of the pressure chamber ( 10 , 17 ) or the suction chamber ( 25 , 31 ) of the compressor-defining wall or at least one projection that extends into the pressure chamber ( 10 , 17 ) or into the suction chamber ( 25 , 31 ). 4. Compressor according to claim 1 or claim 2, characterized in that the wall-like part as a pot-shaped part ( 79 , 80 , 90 , 88 ) is formed, which on a shoulder of the pressure chamber ( 10 , 17 ) or the suction chamber ( 25 , 31 ) of the compressor delimiting wall or at least one projection extending into the pressure chamber ( 10 , 17 ) or into the suction chamber ( 25 , 31 ). 5. Compressor according to at least one of the preceding claims 3 or 4, characterized in that the projection as on the pressure chamber ( 10 , 17 ) or the suction chamber ( 25 , 31 ) of the compressor delimiting wall arranged rib ( 74 , 75 , 81 , 82 ) which extends in the direction of the longitudinal axis of the cylinder head ( 29 , 33 ) and extends transversely to the longitudinal axis of the cylinder head ( 29 , 33 ) into the pressure chamber ( 10 , 17 ) or into the suction chamber ( 25 , 31 ) . 6. Compressor according to at least one of the preceding claims 3 or 4, characterized in that the projection is formed by an end face of a socket inserted into the pressure chamber ( 10 , 17 ) or into the suction chamber ( 25 , 31 ). 7. A compressor according to claim 1, characterized in that the wall-like part of the seal ( 12 ) is gebil det, wherein the seal ( 12 ) is designed as a plate-like part, which is from its clamping area between the cylinder head upper part ( 29 ) and starting from the cylinder head lower part ( 33 ), extending transversely to the longitudinal axis of the cylinder head upper part ( 29 ) and the cylinder head lower part ( 33 ), we at least into the pressure chamber ( 10 , 17 ) and into the further space ( 27 , 30 , 24 , 22 , 27 ' , 30 ') he stretches in such a way that the pressure chamber ( 10 , 17 ) of the seal ( 12 ) is divided into a pressure valve side first pressure chamber ( 10 ) and a pressure connection side second pressure chamber ( 17 ) and the further space ( 27 , 30 , 24 , 22 , 27 ', 30 ') is divided into a first chamber ( 30 , 24 , 30 ') and a second chamber ( 27 , 22 , 27 '), the first pressure chamber ( 10 ) and the second Pressure chamber ( 17 ) on one of the seal ( 12 ) be limited or arranged in the seal ( 12 ) through opening ( 19 ) are connected to each other and wherein the first chamber ( 30 , 24 , 30 ') and the second chamber ( 27 , 22 , 27 ') via a seal ( 12 ) limited or in the seal ( 12 ) arranged further through opening ( 28 , 23 , 14 ) are constantly connected to each other. 8. Compressor according to claim 7, characterized by the following features:

• a) the cylinder head upper part ( 29 ) or the cylinder head lower part ( 33 ) is formed transversely to the longitudinal axis of the cylinder head Zy ( 29 , 33 ) divided;
• b) between the mutually facing end faces ( 63 ) and ( 65 ) of the first part ( 29 a) and the second part ( 29 b) of the cylinder head upper part ( 29 a, 29 b) or between the two parts of the cylinder head lower part ( 33 ) a second you device ( 64 ) arranged;
• c) the second seal ( 64 ) is designed as a plate-like part, which extends from its one clamping area between the first part ( 29 a) of the cylinder head upper part ( 29 a, 29 b) or the first part of the cylinder head lower part and the second part ( 29 b) of the upper part of the cylinder head ( 29 a, 29 b) or the second part of the lower part of the cylinder head, transversely to the longitudinal axis of the upper part of the cylinder head ( 29 a, 29 b) and the lower part of the cylinder head ( 33 ), at least until the in the cycle Lindenkopfoberteil ( 29 a, 29 b) located second pressure chamber ( 17 a, 17 b) or into the cylinder head in the lower part ( 33 ) located first pressure chamber ( 10 ), in such a way that the second pressure chamber ( 17 a, 17th b) or the first pressure chamber ( 10 ) is divided by the second seal ( 64 ) into a first partial chamber ( 17 a) and a second partial chamber ( 17 b), the first partial chamber ( 17 a) and the second partial chamber ( 17 b) one of the second seal ( 64 ) limited or in the two th seal ( 64 ) arranged through opening ( 67 ) are interconnected.

9. Compressor according to claim 7, characterized in that the seal serving as the first seal ( 12 ) is designed and dimensioned such that it extends additional Lich into the suction chamber ( 31 , 25 ) and thus the suction chamber ( 31 , 25th ) divided into a suction port-side he ste suction chamber ( 25 ) and a suction valve-side second suction chamber ( 31 ), the first suction chamber ( 25 ) and the second suction chamber ( 31 ) being limited by a seal ( 12 ) or in the first you device ( 12 ) arranged further through opening ( 26 ) are interconnected. 10. A compressor according to claim 8, characterized in that the second seal ( 64 ) is designed and dimensioned such that it additionally extends into the first suction chamber ( 25 a, 25 b) and into the second suction chamber ( 31 ) and the first suction chamber ( 25 a, 25 b) and the second suction chamber ( 31 ) are divided into a first partial chamber ( 25 a) and a second partial chamber ( 25 b), the first partial chamber ( 25 a) and the second partial chamber ( 25 b) are connected to one another via a through opening ( 69 ) delimited by the second seal ( 64 ) or arranged in the second seal ( 64 ). 11. Compressor according to at least one of the preceding claims, characterized in that the further space ( 27 , 30 , 24 , 22 , 27 ', 30 ') is designed as a coolant channel. 12. Compressor according to claims 8 and 10, characterized in that the second seal ( 64 ) forms out and is dimensioned such that it is also in the first chamber ( 27 a, 27 b, 22 a, 22 b, 27 'a, 27 ' b) of the further space ( 27 , 30 , 22 , 24 , 27 ', 30 ') and this first chamber ( 27 a, 27 b, 22 a, 22 b, 27 'a, 27 'b) divided into a first sub-chamber ( 27 a, 22 a, 27 ' a) and a second sub-chamber ( 27 b, 22 b, 27 'b), the first sub-chamber ( 27 a, 22 a, 27 ' a ) and the second partial chamber ( 27 b, 22 b, 27 'b) are connected to one another via a further passage opening ( 70 , 68 , 66 ) bounded by the second seal ( 64 ) or arranged in the second seal ( 64 ). 13. Compressor according to at least one of the preceding claims, characterized in that the wall-like part ( 12 ) via a rib-like part ( 56 ) with a near the pressure valve ( 5 , 7 ) arranged component, such as a valve catcher ( 8 ), is connected. 14. A compressor according to claim 13, characterized in that the rib-like part ( 56 ) between the Druckven valve ( 5 , 7 ) and the pressure connection ( 54 ) of the cylinder head ( 29 , 33 ) is arranged and together with the wall-like part ( 12 ) separates the first pressure chamber ( 10 ) from a third pressure chamber ( 60 ), the third pressure chamber ( 60 ) continuously communicating with the second pressure chamber ( 17 ) via a further passage opening delimited by the wall-like part ( 12 ) or arranged in the wall-like part ( 12 ). connected is. 15. Compressor according to at least one of the preceding claims, characterized by the following features:

• a) at the bottom ( 34 ) of the cylinder head lower part ( 33 ) between the pressure valve ( 5 , 7 ) and the side of the cylinder head ( 29 , 33 ) arranged Druckan circuit ( 54 ) a rib-like part ( 59 ) is arranged, which is from the floor ( 34 ) of the cylinder head lower part ( 33 ) extends away in the direction of the first wall-like part ( 12 );
• b) on the cylinder head upper part ( 29 ) the rib-like part ( 59 ) opposite another rib-like part ( 57 ) is arranged, which extends from the cylinder head upper part ( 29 ) away in the direction of the first wall-like part ( 12 ).
• c) the further rib-like part ( 57 ) separates the second pressure chamber ( 17 ) located in the upper part of the cylinder head from a third pressure chamber ( 61 ) also located in the upper part of the cylinder head ( 29 );
• d) separating the first rib-like portion (59) in the Zy linder head lower part (33), this first Druckkam mer (10) by a likewise in the cylinder head lower part (33) situated fourth pressure chamber (62);
• e) the first pressure chamber ( 10 ) is connected via a passage opening ( 19 ) bounded by the first wall-like part ( 12 ) to the second pressure chamber ( 17 ), the second pressure chamber ( 17 ) is located above a rib-like part ( 57 ) angeord Nete or by the second rib-like part ( 57 ) and the wall-like part ( 12 ) limited passage opening ( 58 ) with the third pressure chamber ( 61 ) in connection and the third pressure chamber ( 61 ) is via a in the first wall-like part ( 12 ) angeord Nete or by the first wall-like part ( 12 ) be limited through opening ( 55 ) connected to the fourth pressure chamber ( 62 ).

16. Compressor according to at least one of the preceding claims, characterized in that the wall-like part ( 12 , 76 , 64 , 79 , 80 , 90 , 88 ) consists of a metallic material. 17. A compressor according to at least one of the preceding claims, characterized in that the through wall opening ( 77 , 19 ) delimited by the first wall-like part ( 76 , 12 ) is arranged offset with respect to the pressure valve ( 5 , 7 ). 18. A compressor according to at least one of the preceding claims, characterized in that the limited by the first wall-like part ( 12 , 79 , 80 ) through passage opening ( 26 , 78 ) with respect to the suction valve ( 32 , 4 ) is arranged offset. 19. A compressor according to at least one of the preceding claims, characterized in that in the most wall-like part ( 12 , 76 , 79 , 80 ) arranged through openings ( 19 , 77 , 26 , 14 , 23 , 28 , 78 ) and in the second wall-like part ( 84 , 64 , 90 , 88 ) arranged through openings ( 93 , 66 , 67 , 68 , 69 , 70 , 91 ) are arranged offset from each other.