DE1872479U - DIAPHRAGM PUMP. - Google Patents

Description

Kurt Ueuberger K.G., Maschinenfabrik Sch / B Ireiburg / Breisgau File 62 185

Diaphragm pump

The firing relates to a diaphragm pump for vacuum generation, which is open to valves controlled by the pressure differences in the pumping medium and a connecting rod to move the diaphragm. It is already known to use spring-loaded check valves in diaphragm pumps that are used to _{generate vacuum E r} , which are controlled by the pressure differences in the medium to be conveyed. It is also part of the state of the art to move the diaphragms of such pumps by means of a connecting rod. In the previously known designs you have the suction or. Pressure line routed from the valves on the shortest route into the pump room in order to keep the harmful space small. For the same reason, the recess, which forms the upper end of the pump chamber and is usually housed in an intermediate cover, has also been provided with a slightly recessed part for receiving the mounting plate for the membrane on the pump side. This creates a sharp edge on which the diaphragm, which is the most sensitive part of the pump, is particularly stressed.

The diaphragm pumps described above have the advantage of a simple design, since they do not use any controlled valves. on the other hand

the vacuum to be created with them is not very high, since the harmful space is comparatively large and a backflow into the suction connection cannot be completely avoided is. The innovation is based on the task of a To create a diaphragm pump in which the aforementioned Hachteile can be reduced, so that this pump can generate a higher vacuum without the simple Construction of the pump is to be abandoned. The innovation according to the solution is that the mouth of the suction valve Line leading to the pump chamber to "close" by means of the diaphragm in the connecting rod oscillation plane close to that Bin tensioning parts of the membrane is arranged on the this is first raised during operation.

The recess forming the upper end of the pump chamber can expediently be used to form the largest possible contact surface have a continuously running, stepless profile for the membrane.

Further details of the furnace will be explained in more detail using an exemplary embodiment shown in the drawing, It shows

Figure 1 is a vertical cross section through a diaphragm pump,

Figure 2 is a plan view of the valve plate,

FIG. 3 shows a cross section through the pump accordingly Figure 1 with just beginning pressure stroke and

Figure 4- a vertical longitudinal section through the pump.

His pump, designated as a whole by 1 ", has a plug 2 which leads to a membrane 3 which is attached to the mushroom-shaped head side 2a of the connecting rod with the aid of a fastening plate 4 Housing, on the upper side of which there is an intermediate cover 6, which clamps between its lower edge and the upper edge of the housing 5 <over membrane 3. The intermediate cover 6 has a recess 7 which forms the upper end of the pump chamber 8. Above the intermediate cover 6 is a valve plate 9 and above it a closing cover 10 in which a suction connection 11 and a pressure connection 12 are provided , which are each hinged to a resilient tongue 15 or 16 and each protrude into a passage opening 17 or 18. The one in the end cover l 10 located suction connection 11 leads from a connection thread 19 to the top of the suction valve 13. Below this there is a recess 20 in the intermediate cover 6, which allows opening of the suction valve 13 and from which a feed line 21 leads to the pump chamber 8 (Fig. 1). On the other hand, a discharge line 22 is provided in the intermediate cover 6 which connects the pump chamber 8 to the underside of the outlet valve 14. Above the outlet valve 14, a recess 23 is provided then in the cover, which allows an opening of this' valve upwardly and the Y _e rbindung the derivative 22 with the Dpuckanschluß 12 is prepared.

According to the innovation, the mouth 24 of the supply line is now located in the connecting rod oscillation plane near that clamping point 25 of the diaphragm 3 at which it is first raised during operation. This ensures that "when the connecting rod moves in the direction of the arrow 26, the diaphragm 3 closes the supply line 21 at the beginning of the displacement stroke, as shown in FIG the side profile 26 of the recess 7 of the intermediate deck ^ 1 $ 6 formed continuously. Finally, 2, the connecting rod such a mushroom-shaped profiled head 2a in that it is able to press the diaphragm 3 against the mouth 25 of the supply line 21 already at the beginning of the delivery stroke.

When the diaphragm pump for vacuum generation is put into operation and the connecting rod 2 moves in the direction of arrow 26, is the first between the membrane 3 and the intermediate cover 6 remaining pump chamber 8 reduced in size, so that there is an overpressure. The medium in the pump chamber 8

the outlet valve can lift 14 and escape via the outlet 22, the recess 23 and the D _r uckanschluß 12th During the subsequent downward movement of the connecting rod 2 and the diaphragm 3, a negative pressure arises in the pump chamber 8, by means of which the suction valve 13 is opened and the medium to be sucked off is conveyed into the pump chamber. In the initial stage of the displacement stroke that now begins again, not only does the suction valve 13 close, but the membrane 3 also blocks the opening 24 of the supply line 21 at a very early stage

one achieves that the further pressure increase in the pump room 8 no longer affects the Eaum formed by the supply line 21 and the recess 23, in which rather the the same or at least almost the same pressure as in the suction connection 11 prevails. So, in a sense, this is before the suction valve 13 lying Eaum turned off as dead space. On the other hand, the opening 24 is opened in good time by the movement of the connecting rod. Due to the new arrangement the mouth 24 of the supply line 21 can be achieved without additional effort that the membrane 3 as an additional controlled The valve on the suction side of the pump works. The further proposed configuration of the recess 7 in the intermediate cover 6 creates a large contact surface for did membrane 3 and thereby not only enables a good seal of the mouth 24 as well keeping the harmful tree small, but also avoids that the membrane on a sharp edge of the intermediate cover 6 is heavily used. As can be clearly seen from FIGS. 1 and 2, the profiling of the connecting rod head 2a influence the opening and closing times for the mouth of the supply line 21.

Claims (3)

6- P.A. 831245 * 29.1262 1. Diaphragm pump for vacuum generation with the pressure differences valves controlled by the pumped medium and a connecting rod for moving the diaphragm, characterized in that that the opening (24-) of the feed line (21) leading from the suction valve (13) to the pump chamber (8) is closed by means of the diaphragm (3) in the connecting rod oscillation plane near the clamping point (25) of the diaphragm is arranged in which this is first raised. 2. Diaphragm pump according to claim 1, characterized in that the upper end of the pump chamber (8) forming recess (7) to form the largest possible contact surface for the membrane (1) a continuously having extending side profile (27). 3. Diaphragm pump according to claim 1 or 2, characterized in that the connecting rod head (2a) is mushroom-shaped is profiled that at the beginning of the displacement stroke, the membrane (3) against the mouth (25) of the supply line (21) able to apply. J) Patent attorney