DE2061091B2 - HYDRAULIC PULSE GENERATOR FOR INJECTION CARBURETORS - Google Patents

Description

55

The invention relates to a hydraulic pulse generator for injection carburetors for internal combustion engines with a cylinder block having a cylinder bore, with one in the cylinder bore displaceable piston, with a compression space between the piston head and the cylinder head is formed and wherein on the side of the piston opposite the compression space a suction space is formed with a piston rod, with c:, icm push mechanism for the piston rod, which causes the piston rod to move back and forth briefly, causing the medium to move into compresses the compression space during the compression stroke and during the return stroke Medium is introduced into the compression space and the piston consists of a rotationally symmetrical, of the piston rod actuated part and a coaxial to this Tcif in the longitudinal direction of the piston between two stops freely reciprocating riiic-shaped piston part consists.

Such pulse generators for injection gases: are known (Swedish patent specifications 2 245 57 "and 305 980, USA patent specification 2 254 441). In these known injection carburettors, the fuel must! ' an injection nozzle is supplied in pulses under pressure will. The on an elastic valve body ■■ in the opening of the injection nozzle through the focal point Substance transmitted pressure oscillations in this way also generate vibration in the valve body ! boys, who are the prerequisite for the proper functioning of the injection carburetor.

The fuel is injected in such a way: i water supplied by a hydraulic pulse generator, which in the "Prinzin" acts as a piston or diaphragm: ma pump is working. With every pressure surge this * The pump is the Linspritzdüse of the carburetor a ge certain amount of fuel supplied. Practical experiments with such an injection have given \ cr gaser found that the in the pipe and or the Transmission paths between the pulse generator and the pressure vibrations generated by the carburetor must have the form of pressure surges that are hard and are pronounced. The pressure surges then act like a hammer blow on the elastic Vontile body in the injector opening. Practical tests have also shown that e-> with pulse generators of conventional design it is not possible to achieve sufficiently hard and pronounced pressure surges and that, as a result, the injection carburetor is not completely safe and stable in view works on the oscillation processes. This problem has been investigated in a pulse generator which was mounted on a vehicle. It was found that the proper operation of the pulse generator was disturbed by the vibrations of the vehicle. The function of the pulse generator was also negatively influenced by the fact that the Irr pulse generator was mounted at an angle.

The invention is based on the previously described disadvantages of known pulse generators for injection carburetors to avoid.

The object is achieved on the basis of a pulse generator of the type described at the outset in that the one stop of the piston part at the top of one against the piston head is conical inward extending sealing surface of the inner part and the second stop from an approach in the interior Part consists and the annular piston part contains one or more passages through the underside of the annular piston part with a conical, cooperating with the first-mentioned stop Connect the sealing surface in the upper end of this part.

An embodiment of the invention is described below with reference to the drawing. the The drawing shows a longitudinal section through an embodiment.

The pulse generator has a pump housing I.

in which a cylindrical cavity 2 is located part of the inner piston part, d. i.e., both piston ends. The upper part, called the cylinder head, is parts move towards the lower endpomit a shut-off valve 3 provided, which of a sition. In doing so, the compression gap is determined by the Feder4 is preloaded and completely filled with liquid to close off a supply space. to • iffnung5 is used. The opening 5 forms a connection 5 beginning "of the compression shock of the piston, b: \ vetn connection with a pipe that turns only the inner piston part upwards to form an injection scr leads. Inside the cylinder 2 there is a piston 6 until the gap 9 has closed completely. Slidable arranged. The piston consists of rend this phase, the pressure in the compression two Parts, an outer ring-shaped part 7 and sion space not increased considerably as the comeinem substantially cylindrical inner part 8. io pressionsraum over the gap 9 with the suction-der inner part S communicates with space 14 at its upper end. As soon as the gap 9 is closed Part 7 fitted in such a way that when a sen is, the outer piston part also moves Downward movement of the inner part with a conical upward movement and the liquid in the compressor The gap 9 between the two piston parts and the opening space 13 is used by the shut-off valve 3 in FIG. A shoulder 10 on the inner piston part and 15 outlet port 5 printed. From here the A shoulder 11 on the outer piston part defines fluid via a line to an injection nozzle ren the width of the conical gap when that of the carburetor passed v> the.

Piston is moved downwards. The outer piston part The liquid is drawn into the suction chamber of the

WList a number of bushings 12, generated by pulse generator !, by a separate backing pump

ueiche the gap and thus the compression space ^ o presses, which during the whole time a liquid;.! -

13 in communication with the suction chamber 14 promotes the amount of keitsquote from the pulse generator

stands. To center the inner piston part, the amount delivered is considerably in excess. The above-

Fine guide 15 is provided, which is intended to remove the vapor or gas bubbles from the bottom of the schüssige liquid

Pump extends out upwards. Flush a screw 16 from the suction chamber of the pulse generator

interlock the piston with a piston rod 17. the 25 len. Would the gas o ^r vapor bubbles in the presence

remain in a cavity 18 within the guide 15 suction space of the pulse generator, so would

is ordered. In the upper part of the cavity 18 is the "they negatively affect the pump work,

a spiral spring 21 is provided, which is formed on the such vapor or gas bubbles

Kolbensiangensehulter 20 and a flange for volatile liquids, such as gasoline,

Jump 19 is supported on the guide 15 and is particularly easy to 30. As a result of the fact that the

serves to push back the piston. The compression inlet into the suction chamber of the pulse generator

thrust of the piston opens through a cam or tangentially, and the inlet port is so close

caused by an eccentric, the movement of which is as "as possible at the center of the suction chamber,

a pressure shoe 22 is transferred. Of which the suction acts as a separator such that one

Pressure shoe 22 is the adjusting force on one with 35 separation and removal of the in the suction chamber

a stop 24 provided rod 23 transferred located gas bubbles takes place. From the arrival

and liquid flowing back from this via spring washers 25, a sleeve 26 suction chamber can beispids-

and a washer 27 on the piston rod 17. By way of direct or the fuel tank of the car

the elastic spring washers in the power transmission are supplied via a device in which the

The piston stroke is variable and a radio 40 entrained gas or steam bubble is filtered out

tior. des are generated in the compression space 13.

Pressure. This pressure can, on the other hand, be caused by lo- The advantage of the pulse generator described above or tightening the clamps for the tors is obvious. The simplest form of the ex-spring washer can be set. center or cam to generate the piston

The pump housing of the pulse generator contains 45 movement is circular. Such a form has to

two openings, one of which is the inlet 28 result that the piston speed is a sinusoidal

and the other is outlet 29. The inlet 28 is function, i. i.e., the piston speed is reached

leads tangentially and the outlet 29 radially in the \ n then its maximum when the drive eccentric one

suction chamber of the pump housing. From the Auslaßöff- angle of 90 with respect to the longitudinal axis of the Opening 29 extends from a pipe section 30 occupies the 50 piston. In this way it is possible

Suction chamber 14. the distance between the shoulder 10 on the inner

The pulse generator works in the following way: ren piston part and the shoulder 11 on the outer one When the piston is just in its uppermost position piston ^ il adjust so that the gap during the has arrived, the gap 9 is completely closed. Upward movement of the piston at the moment In this case the piston is so high it is closed at 55 where the piston is at a maxidem Cylinder that the top of the piston moves the paint speed. This results in the Cylinder head contacted. As a result, the pressure increase in the compression space is extra-space of the compression chamber 13 practically very fast, which is a hard pulse-like Zero. During the recoil movement of the piston, the result is a surge of liquid moving. Such a shock is Initially only the inner piston part 8, while 60, as already mentioned, is used for the function of a solder outer part of the coli in its uppermost position in a device of extraordinary importance, follow the friction between the piston and the man has found through practical tests that Cylinder remains. This opens the gap 9, with a total piston stroke of 0.70 mm and and the liquid in the suction space 14 is over with a distance of 0.35 mm between the debris Passages 12 and the gap 9 in the compressor 10 and the shoulder 11 give better results with that sion space 13 pressed. If the shoulder 10 erdem on injection carburetor of the type described above inner piston part on the shoulder 11 aims at the., than with comparable known Impulcgeneraäuseren When the piston part touches down, the outer coITors follow.

1 sheet of drawings

Claims (3)

Patent claims: 1. Hydraulic pulse generator for injection carburetors for internal combustion engines with a cylinder block having a cylinder bore, with a piston displaceable in the cylinder bore, with a compression space between the piston head and the cylinder head is formed and wherein on the opposite side of the ig compression space of the A suction chamber is formed with a piston rod, with a push mechanism for piston the piston rod, which causes the piston rod to move back and forth briefly, whereby the medium in the compression space is compressed during the compression stroke and during the return stroke medium is introduced into the compression chamber and the piston from a rotationally symmetrical, from the KoI-benstange actuated part and a piston coaxial to this part in the longitudinal direction iL-s between two stops freely movable to and fro annular piston part, characterized in that one of the impact of the piston part (7) at the top from an inwardly tapering towards the piston head Sealing surface of the "inner part (8) and the second stop from a projection (10) inside Part consists and the annular piston part (7) contains one or more passages 12), the underside of the annular piston part (7) with a conical, with the first-mentioned stop connect cooperating sealing surface in the upper end of this part. 2. Hydraulic pulse generator according to claim 1, characterized in that in the cylinder head a shut-off valve (3, 4) is provided which contains a valve cone (3) which passes through a spring (4) counter to the compression effect of the piston (7, 8) in its closed position is pressed. 3. Hydraulic pulse generator according to claim 1, characterized in that the below of the piston (6) arranged suction chamber (14) is annular and concentric to the inner Piston part (8) is that an inlet port (28) is provided for the suction space (14), which tangentially into the suction space (14) on their Periphery opens, and that an outlet (29) is provided for the suction space (14), which extends radially outward from the central area the suction chamber (14) extends.