DE3214048C2 - Intake manifold assembly for internal combustion engines, in particular for motor vehicles - Google Patents

Abstract

An intake manifold assembly for internal combustion engines, in particular for motor vehicles, has an upwardly open distributor space, on the connecting piece of which a downdraft carburetor is flanged, and intake manifold arms extending from the distributor chamber in a fan-like manner, lying approximately in a horizontal plane and leading to the individual cylinders of the internal combustion engine in such a way that the fuel-air mixture flowing vertically downwards from the carburetor must be deflected in the distributor chamber by 90 ° or essentially by 90 ° in order to reach the intake manifold arms. The rear wall of the distributor space connection piece, which is opposite to the connections of the intake manifold arms, is designed with an inclined surface in such a way that the wall slope protrudes into the downwardly directed fuel-air mixture flow. An intake manifold arrangement configured in this way has the advantage that partial reliquefaction of the fuel-air mixture prepared in the carburetor and thus the formation of creep fuel can be avoided without great expense. This leads to a reduction in fuel consumption, an improvement in the mixture distribution and thus a considerable improvement in the efficiency of the engine. The above measures also result in a significant improvement in the functionality of the engine in the critical cold phase and at low speeds.

Description

The invention relates to an intake manifold for internal combustion engines, in particular for motor vehicles, with an open upstairs room, a downdraft carburetor is to be flanged onto the connecting piece, and from the distributor chamber fan-like outgoing, roughly in a horizontal plane lying intake manifold arms that lead to the individual cylinders of the internal combustion engine.

Internal combustion engines working according to the Otto principle, the downdraft carburettors for fuel atomization use, have a space below the carburetor connection on the intake manifold, which is, as it were, a Represents "intersection" for the fuel-air mixture flows. This room also serves as a Collection and distribution space for the fuel-air mixture fed from the carburettor to the individual suction ducts. In the following, the term “distribution room” will always be used in connection with this room will.

In known intake manifold constructions of the type mentioned at the beginning, the fuel-air mixture flows from the above carburetor in a vertical direction down into the distributor chamber and hits first on the bottom of the latter. Due to the impact and the negative pressure conditions prevailing in the distributor space the fuel-air mixture is then transferred to the individual suction arms of the intake manifold the suction channels of the individual cylinders of the internal combustion engine are connected, diverted.

US Pat. No. 2,175,438 should be mentioned for the related prior art. The intake manifold arrangement disclosed there has a distributor space connection piece, the rear wall of which is inclined (backwards) is that the one directed from the carburetor nacli below Fuel-air mixture flow is given the opportunity in the direction of the distributor chamber (i.e. downwards zu) to move backwards, so to speak, resulting in a disadvantageously acute deflection angle (smaller 90 °) in the direction of the intake manifold arms.

In another, through the DD-PS 55 863 known intake manifold neither has the Manifold connection piece nor does the manifold itself have an inclined surface ?. The distribution room has dagcg-n a curvature directed towards the intake manifold arms, which is very undesirable in terms of the mixture distribution Has an impact. Because the curvature of the distributor space itself becomes part of the The mixture flowing back into the distributor chamber is deflected upwards in an inexpedient manner. The distribution space itself should therefore be essentially cylindrical so that it can flow backwards, Remaining mixture amount remains in the distributor chamber and from there during the intake process of the next one Cylinder can be sucked in. This process would be made more difficult if - as with the subject of the DD-PS 55863 - part of the mixture previously deflected upwards would. It is: therefore essential for the function of an intake manifold arrangement of the type mentioned at the beginning, that the distributor space itself has no inclined surface.

In another intake manifold - made known by US-PS 36 67 432 - has neither

the distributor space itself nor the distributor space connecting pieces a bevel or curvature. The manifold connection piece is only as a whole arranged slightly inclined. An optimal mixture distribution can also be achieved with this known arrangement do not realize.

In the sense of an optimal energy utilization of the fuel and thus also an efficiency optimization the internal combustion engine, it is advantageous if fuel and air, which in the carburetor to one gaseous fuel-air mixture are converted through the intake manifold to the individual cylinders be transported in an unchanged gas state. This requirement may be known from those described above Suction pipe arrangements are not met satisfactorily. As already indicated, there are rather in the known intake manifold assemblies on the way of the fuel-air mixture from the carburetor to to the individual cylinders of the internal combustion engine several deflection points, which are detrimental to the Vergasungsßrad of the mixture. The greatest change in direction is made possible by the fuel-air mixture at the bottom of the distribution room, where it is deflected from a vertical to a horizontal direction of 90 °. Due to the vertical impact of the fuel-air mixture flow on the floor of the distributor chamber segregation occurs (partial conversion of the finely atomized fuel from the gaseous state in liquid form). The one transformed back into a liquid state Fuel Anleil can convert up to 40 percent of the total amount in the carburettor into a fuel-air mixture Amount of fuel. It is referred to as a so-called creep fuel because it has more or Less uncontrolled flow through the intake manifold Admittedly, the creeping fuel through the intake manifold system (after reaching the operating temperature of the engine) prevailing temperatures by heating again converted to the gas state. However, this type of conversion also results in the suctioned-in heating being heated Air cannot be avoided. Disadvantageously, this leads to a severe reduction in the degree of delivery of the engine.

Another major disadvantage of the one described known intake manifold is that due to the formation of creep fuel a perfect Functioning of the engine is prevented during the critical phase of running.

In summary, the following disadvantages caused by the formation of creep fuel can be mentioned will:

1. Increased fuel consumption.

2. Deterioration of the mixture distribution, which as a result leads to a deterioration in efficiency of the engine leads.

3. Reduction in the functionality of the engine in the cold phase and at low speeds.

The object of the present invention is to provide an intake manifold assembly of the type identified at the beginning to design that largely avoided the formation of creep fuel without great effort and thus the disadvantages mentioned above are eliminated.

According to the invention, the object is achieved in that the opposite to the connections of all Intake pipe arms lying rear walls of the distribution room connection piece.p each form a conical surface, the rear wall slope formed in each case protrudes in all vertical planes into the downwardly directed fuel-air mixture flow, and that the transition cross-section of the distributor space connecting piece into the distributor space is oval or essentially 5 is oval

The measures according to the invention allow the process of deflecting the fuel-air mixture within divide the distributor chamber into two stages, thereby redirecting the fuel-air mixture

ίο takes place in a much gentler form than with known, the intake manifold arrangements described above, where the fuel-air mixture is perpendicular to the bottom of the Manifold meets.

Since the measure according to the invention of deliberately arranging inclined surfaces within the distributor chamber connection piece, as such, already has a very advantageous effect with regard to the prevention of creep fuel, the desired effect in an advantageous development of the invention can be increased even further by the fact that the resultant of the inclined or conical rear wall area: ys distributor chamber connection piece resulting reduction of the inner cross-sectional area in the direction of the fuel-air mixture entering the distributor chamber is compensated by a corresponding expansion of the inner cross-section in the transverse direction.This measure advantageously ensures that the fuel flow rate is as constant as possible -Air mixture and the restriction of dead space to a minimum.

Further advantageous refinements of the invention can be found in the subclaims and on the basis of Exemplary embodiments - refer to the drawing and the following description of the drawing. It shows

F i g. 1 - in plan view - an intake manifold for a four-cylinder internal combustion engine with a simple Downdraft carburettor,

Fig. 2 is a section along the line H-II in F ig. 1.

3 shows an embodiment of a suction pipe arrangement for a four-cylinder internal combustion engine with a double downdraft carburetor, in a plan view corresponding to FIGS
F i g. 4 shows a section along the line IV-IV in FIG. 3.

According to FIGS. 1 and 2, the designated 10 as a whole has Suction pipe assembly has a central housing part 11, which has a distribution space numbered 12 encloses. A total of four suction pipe arms go from the central housing part 11 or from the distributor space 12 13 to 16, which are arranged in a fan shape, lie in a horizontal plane and to the individual Lead intake manifold channels (not shown) of the internal combustion engine. The attachment of the suction tube arms 13 to 16 at the associated suction channels of the internal combustion engine takes place in each case by means of flanges, one of which is shown in FIG. 2 and numbered 17.

V / ie furthermore in particular from FIG. 2 is apparent Above the central housing part 11 that forms the distributor chamber, a distributor chamber connecting piece is provided 18 which has a flange 19 at its upper end. The flange 19 is used to attach one shown in Fig. 1 and / 2micht * Downdraft carburetor of the usual design. Only the throttle valve of the carburetor is shown in two different ways Positions indicated and denoted by 20 and 20 '. 20 here indicates the open position the throttle valve, whereas the position 20 'prevents a half-closed position of the throttle valve

5 6

symbolic. designated. A partially closed position of the

The fuel-air throttle valve 20a or 27 prepared in the carburetor is indicated by the arrow 21 in FIG. 27 'illustrated.
Carburetor vertically downwards into the connecting piece According to Fig. 3 and 4, the connecting piece 18a of the 18 of the Vcrtcilcrraumes 12 is a. 2 makes it clear, 5 distributor space 12a through an intermediate wall 28 so that here a first deflection of the mixture flow is designed that it appears at the level of its connecting flange (arrow 21) in the direction of the suction pipe arms 13 to 16 19a two inlet cross-sections 29 and 19a 30 for which follows. The fuel-air mixture flow from the dopant-air mixture flow illustrated by the arrows 21 then meets the corresponding downdraft carburetor. 3 reveals that the two inlet cross-sections 29, 30 each circle up at an angle to the bottom 22 of the distributor space 12 io. wherein they are again formed in the direction of the suction tube arms. Which is deflected by the partition 28 13 to 16. In this way, the fuel-air mixture formed in the manifold connection stub 18a reaches the intake manifold arms 13 to 16, one behind the other. The - similar to the execution internal combustion engine. 15 shape according to Fig. 1 and 2 - obliquely formed

As FIG. 2 shows, the first stage of the shielded rear wall areas of the connection channels 31, 32 takes place

The second double deflection of the fuel-air-Ge are numbered in FIG. 4 with 33 and 34, respectively. Fig.3 leaves the

mixed flow within the distribution compartment connection - correspondingly conical design (see

Stutzens IS, and indeed sn the hatched surface area marked with 23? f * b? ^w FA Her srhräiyflä-

wall of the same, which, due to their inclination, recognize space-like rear wall areas 33 and 34, respectively. Even

In turn, the shape of the fuel-air mixture flow changes

(Arrows 21) protrudes From Fig. 1 it can be seen that the cross-sectional areas of the connection channels 31,32 from the

to the carburetor (not shown) immediately starting with a circular shape (29, 30) up to an oval

Closing inner cross-section of the distribution space-shape (dashed lines 35 and 36 in Fig. 3) on the

connecting piece 18 is circular. The height A of the suction pipe arrangement (Fig. 4).

the appropriate inlet opening is shown in FIG. 1 in solid lines. A special feature of the embodiment according to FIG. 3

Circle line shown and denoted by 24. The height and 4 lies in the fact that the inclined intermediate

this inlet cross section 24 is shown in FIG. 1 and 2 also include the sloping rear wall

corn marked by the capital letter E. 34 of the front connection carial 32 and the cntsprc-

F i g. 2 furthermore makes it clear that the front wall, which has a sloping surface, is denoted by 37

formed rear wall 23 of the distribution space connection pipe - the rear connection channel 31 is formed. Select

zens 18 up to that in Figure 2 with the letter Λ rend the rear wall 33 of the rear connection channel 31 Li

marked height runs At this height there is a relatively strong inclination of about

the outlet cross-section of the vertex, denoted by 25, is 45 ° to the horizontal or to the vertical

lerraum-Anschiußstutzens 18. From Fig. 1 it can be seen 35 the inclined surface formed by the partition 28

that this outlet cross-section 25 - as in dashed surfaces 34 and 37 formed less inclined, d. H.

Line indicated - has an oval shape. The distributor has a greater steepness. The one above the

ler space connection piece 18 is designed so that connections of the suction pipe arms 13 to 16 lying in front

its inner cross-section of the initial circular shape re wall area 26a of the front connection channel 32 is

24 (or E), on the other hand, due to the sloping rear wall 40 - as in the case of the embodiment

23, continuously into the oval cross-sectional shape 25 over to FIG. 1 and 2 - directed vertically

goes. However, the size of the inner transverse remains here. Another special feature of the embodiment

always cut the same. Due to the sloping formation according to Fig.3 and 4 is that the length of the

Application of the rear wall area 23 of the distributor space to distributor space connection piece 18a (vertical distance

connecting piece 18 receives the interior of the distributor 45 between planes E and A) and the inclined position

space connection piece 18 in its rear side of the rear wall 33 of the rear connection channel 31 so

rich (see. Projection F in F i g. 1) a conical are matched to each other that the relevant

Shape. Fuel-air mixture flow (arrows 2Ia ^ in the

The numbered with 26, above the mouths of the rear connection channel 31 flows in almost in his

Suction tube arms 13 to 16 lying front wall area 50 entire cross-sectional area on the inclined surface

of the distribution room-A:; the connecting piece 18 is on the other hand, as the rear wall 33 strikes and accordingly to the front uvn-

F i g. Fig. 2 shows being steered vertically.

The embodiment according to FIG. 3 and 4 differ

det differs from the embodiment according to FIGS. 1 and 2 for this purpose 2 sheets of drawings

basically in that the suction pipe arrangement according to 55

F i g. 3 and 4 is designed for a double downdraft carburetor. In the interests of clarity and clarity, the embodiments to be compared are shown in FIG
F i g. 3 and 4 have the same reference numerals for corresponding parts as in FIG. 1 and 2 have been used. At 60
The relevant reference symbols are used for deviations
the embodiment according to FIG. 3 and 4 only through
the letter "a" has been added. The one in question
Double downdraft carburetor is also shown in FIG. 3 and 4 do not
shown as it is not an integral part of the 65
Finding represents In Fig.4 only the two are
Throttle valve of the carburetor indicated and - in the
Open position - by dashed lines 20a and 27, respectively

Claims (7)

Patent claims: 1. Saugrohrajiordnung for internal combustion engines, in particular of motor vehicles, with an upwardly open distribution room, on whose connection piece a downdraft carburetor is to be flanged, and with intake manifold arms extending from the distributor chamber in a fan-like manner, lying approximately in a horizontal plane, which lead to the individual cylinders of the internal combustion engine , characterized in that the rear walls (23 or 33 or 34) of the distributor chamber connection piece (18, i & a) lying opposite the connections of all suction pipe arms (13-16) each form a conical surface, the rear wall slope (23, F or 33, F, or 34, F ₂ ) protrudes in all vertical planes into the downwardly directed fuel-air mixture flow (21 or 2 \ a) , and that the transition cross-section (25 or 35 bz'A - ". 36) of the distribution space connecting piece (18 or iSa) in the distribution space (12 or 12a) is oval or essentially oval. 2. Suction pipe arrangement according to claim I _1, characterized in that the resulting reduction of the manifold chamber connection piece (18 or 18a ^ resulting from the inclined or conical rear wall area (23, F or 33, Fi or 34, F>) of the Internal cross-sectional area in the direction of the fuel-air mixture entering the distributor chamber is compensated for by a corresponding widening (25 or 35 or 36) of the interior; quersc \ nitts in the transverse direction. 3. manifold assembly according to Ar · Pruch 1 or 2, characterized in that the length (distance A to £ / the Veneiierraum-AnschiuBstuizens (Isä / and the inclination of the rear wall (33) thereof are matched so that the fuel-air Mixture flow hits the sloping rear wall (33) of the distributor space connection piece (18a; 4. suction pipe arrangement according to one or more of the preceding claims, characterized in that that the front wall area (37) of the manifold connection piece (18a; in the sense of the inclination of the rear wall area (33) is also formed with an inclined surface (FIGS. 3 and 4). 5. intake manifold according to claim 4, with double downdraft carburetor, wherein the connection piece of the distributor space in two one behind the other Connection channels is divided, characterized in that the sloping rear wall (34) of the front Connection channel (32) at the same time the correspondingly sloping front wall (37) of the rear Connection channel (31) forms. 6. suction pipe arrangement according to claim 4 or 5, characterized in that the sloping rear wall area (33) of the connection channel (31) of the manifold connection piece (ISa) a / lower steepness (ie a greater inclination) than the sloping front wall area (37) having. 7. Suction pipe arrangement according to claim 5, characterized in that the front wall region (26a) of the front connection duct (32) of the distributor space connection piece (18a ^) which is above the connections of the suction pipe arms (13-16) is directed vertically.