WO1985003741A1

WO1985003741A1 - Additional air supply device for carburators of internal combustion engines

Info

Publication number: WO1985003741A1
Application number: PCT/AT1985/000002
Authority: WO
Inventors: Ferdinand Ocenasek
Original assignee: Trenner, Otto, Sen.
Priority date: 1984-02-14
Filing date: 1985-02-05
Publication date: 1985-08-29
Also published as: EP0172180A1

Abstract

Device for supplying additional air to carburators of internal combustion engines, comprising an intermediary member (1) arranged downstream of the carburator, with a passage opening configured like a venturi tube and surrounded by an annular channel (3) which communicates, by means of a supply channel (5) with the atmosphere, and, by means of oblique slots provided in the narrowest cross-section area of the passage opening, with the inside of the section pipe. The supply channel (5) has a channel segment (13) which conically widens in the additional air flow direction and which may be closed by a spring-urged ball (8).

Description

Additional air supply device for carburetors of internal combustion engines.

The invention relates to a device for the supply of additional air in carburetor engines, consisting of an intermediate member which can be inserted downstream of the carburetor into the intake pipe or is fixedly mounted in the intake manifold with a flow nozzle-like flow opening corresponding to the cross section of the intake pipe.

A number of devices are known which, by introducing additional air after the dosing valve of the carburetor, should enable the air-fuel mixture drawn in by the engine to become leaner, in order in this way to reduce both the fuel consumption and the emission values (CO and HC + NO _x ). to reduce.

The invention has for its object to provide a device for supplying additional air in carburetor engines, which allows exact metering of the additional air over the entire operating range of the engine and which, especially in the idle and part-load range, an improved mixture preparation and thereby an improved Geraisch distribution to the individual cylinders. This is achieved according to the invention in that the supply air duct is split into two parallel sub-ducts within the intermediate member, which are combined again into a single duct before they enter the ring duct, and in that the one sub-duct has a duct section which widens conically in the direction of flow of the additional air and which in the area of the narrowest point by a valve body loaded by a spring, e.g. by a ball that can be closed. Around the central opening of the intermediate member there are preferably obliquely arranged slots as connecting channels between the annular channel and the suction line.

The metering of the additional air takes place advantageously depending on the prevailing intake manifold vacuum in that, depending on the intake manifold pressure, the valve ball is lifted from its seat more or less, which, due to the conical expansion of the channel in the region of the valve ball, opens up a larger cross-sectional area with increasing vacuum The flow characteristic can be easily adapted to the operating range of different engine types with good accuracy. At the same time, in addition to the exact supply air metering due to the inventive design of the connecting channels between the ring channel and the Intake line also improved mixing of the supply air can be achieved with the air-fuel mixture supplied to the carburetor, since the oblique arrangement of the slots causes a certain swirl flow in the narrowest cross section of the ring used, which also leads to a detachment from the liquid fuel that is present the intake manifold walls has come down, especially when idling and at low loads, i.e. with the throttle valve strongly turned, the flow in the area of the throttle valve is very one-sided, so that a large part of the collapsed fuel flows in liquid form along the intake manifold walls, whereby certain cylinders are preferred in the supply of fuel. The connecting channels in the form of slots that cover almost the entire circumference of the narrowest. Cover cross-section, therefore make it possible to detect a very large proportion of the fuel introduced even in the lowest part-load area even with one-sided flow and to detach a wall film in the form of liquid fuel from the intake manifold wall and to provide an improved mixture preparation.

According to a further feature of the invention, the bias of the spring for the valve body can be changed by means of an adjusting screw screwed into the intermediate member. This makes it possible to change the point of use of the supply air supply via a subchannel, which above all gives advantages in terms of adapting the device according to the invention to different engine types. Furthermore, the flow characteristics through the valve can also be changed to a certain extent and the device can thus be better adapted to the operating range of the respective engine.

According to a further feature, the seat of the valve ball can be armored and ground, as a result of which the exact dosage of the valve Set air is retained over a very long period of operation, since the valve ball cannot be worked into the seat and the contour of the cross-sectional expansion cannot change. Grinding the reinforcement ensures a tight fit of the valve ball, so that the valve's point of use, once set, is retained exactly over a long period of operation.

According to the invention, it can also be provided that the two subchannels each open into the annular channel. The supply of additional air to the ring channel or the distribution of the additional air in the ring channel can thus be further improved by arranging the opening of the sub-channels appropriately. In addition, in some cases, a disadvantageous mutual influence of the two sub-channels is avoided.

Furthermore, it can also be provided that the supply air duct, the partial ducts, the cross-sectional expansion with the valve ball and the spring and the adjusting screw are arranged in a separate duct body. In this case, there are manufacturing advantages because the channel body can be manufactured independently of the intermediate flange. Advantageously, the channel body can e.g. be an injection molded part, but also consist of a heat, petrol and oil resistant plastic.

Between the carburettor shown and the intake manifold of the engine is a flange-like intermediate member 1. The intermediate member 1 has a central bore into which a valve-nozzle-like ring is inserted. Between the inner part of the intermediate member 1 and and the insert, an annular channel 3 is recessed, from which connecting channels lead through the insert in the area of the narrowest cross section into the interior of the suction line 4. The connecting channels are designed as slots which are arranged obliquely with respect to the flow direction 4 of the intake mixture and which bridge almost the entire circumference of the narrowest cross section of the insert.

In the exemplary embodiment according to FIG. 3, the intermediate link 1 has an attachment on one side, in which there is an air supply duct 5 which splits into sub-ducts 10 and 11.

In the subchannel 7 there is a cross-sectional widening which is conical in the direction of flow of the additional air and can be closed by a spring-loaded valve ball 8 in the area of its narrowest point. The conical cross-sectional expansion and the valve ball 8 together form a flow system based on the float principle. Depending on the pressure difference before and after the valve ball and the preload by the spring, a larger cross-section of the sub-channel is released with increasing ball stroke, thus increasing the flow of the additional air. The spring is supported on one side on the valve ball 8 and on the other side on an adjusting screw 9, which is screwed into the shoulder and with which the spring preload can be changed. This makes it possible to change the opening point of the valve and also to adjust the flow characteristics through the valve according to the different requirements for different engines.

In the direction of flow, after the conical cross-sectional widening in subchannel 7, an adjusting screw 10 is provided, which is also screwed into neck 2 and which is provided with a conical tip. The adjusting screw 10 serves to limit the maximum flow through subchannel 7, by performing a conical one A very sensitive adjustment of the additional air is possible. The cross section of the second subchannel 6 can also be changed by an adjusting screw 11, which is also screwed into the extension 2. The two subchannels 6 and 7 are merged into a single channel after the adjusting screws 10 and 11, which opens into an annular channel 3 of the intermediate member 1. However, it is also possible for the two subchannels 6 and 7 each to be separate, e.g. to open into the ring channel at opposite points. FIG. 3 shows a closure plug 12 which is insignificant for the invention, but is necessary for the production.

Arranged in the subchannel 7 is a cross-sectional widening which is conical in the direction of flow of the additional air and can be closed by a spring-loaded valve ball 8 in the area of its narrowest point. For engines with smaller displacements, the Kebei angle 24 is approximately 16 degrees, for engines with a displacement of over 2000 cm up to 24 degrees A larger displacement is required because, according to the larger displacement, more additional air must also be supplied. This is achieved in that the valve cross-section released with the same valve ball stroke is correspondingly larger due to the larger cone angle. The reinforcement of the seat of the valve ball 8 is primarily for durability The device according to the invention is of great importance. This prevents the valve ball 8 from being worked into the seat and the associated change in the flow characteristics. The length of the conical cross-sectional widening 13 is directly related to the cone angle 24 °. As an example, some dimensions are given as guidelines for engines with a smaller displacement:

With a diameter of the subchannel of 4 mm, the diameter of the valve ball 8 is 3.5 mm, the largest diameter of the cross-sectional expansion 9 now and the length of the conical cross-sectional expansion 12 mm.

By means of the device according to the invention, the supply air supply and the combustion process are also optimized to such an extent that, in addition to the considerable fuel savings, the emission values (CO and HC + NO _x ) are below the permissible values even without the use of catalysts, which makes the switch to unleaded fuels essential facilitated.

LEGEND FIG. 1

a Air correction nozzle a1 Fuel inflow b Outlet arm with pre-atomizer c Injection pipe d Enrichment valve e Float needle valve e1 Pump diaphragm e2 Float g Main nozzle v Throttle valve

Claims

PATENT CLAIMS

1.Device for supplying additional air to the carburetors of internal combustion engines, consisting of an intermediate element which can be inserted downstream of the carburetor into the intake line or which is fixedly connected to the carburetor, with a venturi-type flow opening corresponding to the cross section of the intake line, which is formed by an annular ring inserted into the central opening of the intermediate member Body is formed which, together with the inner wall of the intermediate member, forms an annular gap which communicates with the atmosphere via an air supply duct and via a larger number of connecting ducts arranged in the region of the narrowest cross section of the annular body, characterized in that the Supply air duct 5 within the intermediate member 1 is split into two parallel subchannels 6 and 7, which are merged again into a single subchannel 2 before they enter the ring duct 3 and that the partial duct 7 has a duct section 3 which widens conically in the direction of flow of the additional air and which in the region of the narrowest point is supported by a valve body loaded by a spring, e.g. can be closed by a ball 8 and that the connecting channels between the ring channel 3 and the suction line 4 are preferably designed as slots 1a arranged obliquely to the direction of flow.

2. Device according to claim 1, characterized in that the bias of the spring of the valve body can be changed by means of an adjusting screw 9 screwed into the intermediate member.

3. Device according to claim 1 and 2, characterized in that the subchannels 2 and 7 are each variable in their cross section.

4. Device according to claims 1 to 3, characterized in that the organs for changing the cross section of the two sub-channels 2 and 7 in the intermediate member 1 screwed te screws 10 and 11 with preferably tapered

Are great.

5. Device according to claims 1 to 4, characterized in that the adjusting screw 10 for the subchannel 2 is arranged in the flow direction of the additional air after the conical cross-sectional widening 13.

6. Device according to claims 1 to 5, characterized in that the seat of the valve body 8 is armored and ground.

7. Device according to claims 1 to 6, characterized in that the two sub-channels 2 and 7 each open into the ring channel 3 for themselves.

8. Device according to claims 1 to 7, characterized in that the supply air duct 5, the sub-ducts 2 and 7 with the cross-sectional widening 13, the valve body 8 and the spring and optionally the adjusting screws 9, 10 and 11 are arranged in a separate duct body that the connection between the intake manifold and the carburetor is made via an intermediate flange.