DE6939387U - DIAPHRAGM PUMP - Google Patents

Description

The innovation concerns a diaphragm pump in particular for vacuum generation, which has a membrane that is chiped into the edges and deflectable by a connecting rod,

approximately/

those formed at the top of a / mushroom-like Head of the connecting rod is attached by means of a disk engaging in the delivery chamber.

Such pumps are already known per se. The disadvantage of these known pumps is that between the Fastening disk and the inner wall of the conveying chamber usually do not have a relatively large dead space can be avoided. This ^ otraum has so far been caused by the fact that the fastening disk is well in a top dead center corresponding recess had to be introduced. It also played a role that this disc a tilting movement or oscillating movement when the pump rotates carried out. In particular, panes with an approximately rectangular cross-section when viewed from the side resulted in large dead spaces.

This also resulted in bevelled mounting disks however, due to the above reasons in disadvantageous Way a good vacuum generation hindering dead spaces. These dead spaces could also arise because the Diaphragm in top dead center with the inner wall of the pumping chamber could form pocket-shaped cavities, which a prevented as far as possible emptying of the conveying chamber.

The object is therefore to create a diaphragm pump of the type mentioned at the outset, in which these disadvantages can be eliminated and dead spaces in the conveying chamber are avoided as far as possible.

As a solution, the innovation proposes a diaphragm pump of the type mentioned at the outset, which is primarily characterized by this is that the pumping chamber, the top of the connecting rod head and the fastening disc are each as a cone or truncated cone or the like. are formed and have the same base angle between their lateral surfaces and their base surfaces, wherein the wall of the pumping chamber is designed as a hollow cone or truncated cone, and that the distance at the top dead center of the membrane from the outer surface of the connecting rod head to the outer surface of the pumping chamber is equal to the thickness of the membrane and that the lateral surface of the body forming the fastening disk at the top dead center is approximately in the upper surface of the

steered membrane continues. By such an arrangement one achieves an extensive avoidance of dead spaces. ^ In particular, the same angles of the individual cone bodies

and the choice of a distance between the connecting rod end and the conveyor

^: room inner wall equal to the thickness of the membrane prevented

a pocket formation between the membrane and the inner wall of the pumping chamber, since the membrane is at least in the top dead center of the connecting rod head just touches the inner wall of the pumping chamber. The continuation of the upper membrane surface approximately into the upper surface of the fastening disk also results in the area of the fastening disk an extensive avoidance of dead spaces in the upper Τοΐρυτ.κΐ of the pump. The conical training has it the advantage that despite the oscillating movements of the connecting rod, a good entry into the delivery space is made possible and this Distances that take into account tilting movements can largely be avoided.

It is useful if the base angle and the diameter of the membrane, the fastening disc and the flat support surface on the connecting rod head and the connecting rod stroke are coordinated in such a way that the permissible expansion of the membrane material is not exceeded in the outer end positions. In this way, by selecting the design data and, taking into account the membrane material, find a favorable base angle for the individual conical surfaces. Here can the base angle be about 10 to 2 5.

It is useful if, at the top dead center of the pump diaphragm, the distance between an upward extension of the lateral surface of the truncated cone forming the connecting rod head and the surface of the fastening disk is slightly less than the thickness of the non-tensioned membrane and if the fastening disk is one of these Deviation from the diaphragm thickness has a corresponding distance from the inner wall of the conveying chamber. This small distance between the fastening disk and the wall of the conveying chamber at top dead center can be matched to the bearing play, manufacturing tolerances and the pivoting movement of the connecting rod in this way, however, unwanted contact between the fastening disk and the inner wall of the delivery chamber is avoided the diaphragm in the area of this outer edge of the connecting rod head is below the permissible value for the respective material. This reaching in of the connecting rod head into the edge area of the membrane results in a good contact of the membrane in the top dead center on the conveying chamber wall, since the membrane is supported very widely. However, in this edge region by the rolling and pivoting movement of the connecting rod and its KONFES before or after the top dead center of a Zut -.- mniPndrücken the membrane caused, which is the lower, the ^ ^er -. ^R -, ^"it din ^ e pivoting movement. This pivoting movement can be achieved by the

This measure must be kept low, since the stroke is the same a longer connecting rod performs a smaller pivoting movement. If necessary, the outer edge of the connecting rod head can also be rounded somewhat, adapted to this movement

The close contact of the diaphragm at the top dead center on the inner wall of the pumping chamber in the area of the connecting rod head enables the opening of the supply line leading from a suction valve to the pumping chamber to be closed by means of the diaphragm in the connecting rod rocker plane near the clamping point of the diaphragm at which this is first lifted or comes to the system. Because of the good contact of the membrane in this area, this opening can be ^{closed in each case "1} Ut, so that a backflow of the conveying medium into the suction connection is largely avoided.

In the following, the innovation with its it is essential to the innovation associated details explained and described in more detail with reference to the drawing. It shows:

1 shows a cross section through the membrane pump according to the invention, where the membrane is just at top dead center

χ Generation ^ '

Fig. 2 is a schematic representation of the base angle for the outer surfaces of the connecting rod head, the Bef er ti.-TungRr ^ heibe and ier Förderra ^ m internal wind.

A pump designated as a whole by 1 has a connecting rod

2, which leads to a membrane 3, which with the help of a fastening disk 4 on the mushroom-like head 5 of the connecting rod 2 is attached. The connecting rod 2 and possibly its drive are housed in a housing 6 on which At the top there is an intermediate cover 7, which is between its lower edge and the upper edge of the housing 6, the membrane

3 clamps. Furthermore, the intermediate cover 6 has a recess which forms the upper end of the conveying space the pump forms.

Above the intermediate cover 7 is a valve plate 8 and above it a closing cover 9 'in which a suction connection is located 10 and a Druckar.schluss'fi are provided. the Ventilplatxe 8 is largely between the two covers and 9 clamped and has two valves 12 and 13 known per se.

According to the innovation, the front space, the upper side of the connecting rod head 5 and the fastening disk 4 are each designed as a cone or truncated cone. These truncated cones each have the same base angle O { between their lateral surfaces and their base surfaces. The 14 of the Pöra space located in the intermediate cover 7 is thin as a hollow truncated cone.

stalt. In Pig. 1 it is shown that in the top dead center of the membrane 3, the distance A from the lateral surface 5a of the Fleuelkopfes 5 to the lateral surface 14 of the conveying chamber the same the thickness of the membrane 3 and that the lateral surface 4a of the body forming the fastening disc 4 in the upper Dead center is approximately in the upper surface 3a of the deflected Membrane 3 continues. It can be seen that through these geometrical arrangements there is a harmful or dead space in the upper part Dead center of the membrane 3 is largely avoided.

In Pig. 2 the relationship between the base angle OC j, the diameter D of the membrane 3 »the diameter d of the base surface of the fastening disk 4 or the flat contact surface 5b of the connecting rod head 5 and the stroke is shown. According to the innovation, these dimensions have been chosen so that the base angle O (and the diameter D of the membrane 3 »the diameter d of the fastening washer 4 or the flat contact surface 5b of the connecting rod head 5 and the connecting rod stroke H are coordinated in such a way that the permissible expansion of the membrane - Material is not exceeded in the outer end positions. In FIG Upper dead center means deflected membrane 3. It can be clearly seen that the angle O (_ results between the line doors L1 and L2. With this deflection of the membrane, the permissible expansion of the membrane

Material are not exceeded.

It is useful if the base angle OL is approximately 10 ° to 25 °, depending on the pump size.

In Fig. 1 it is also indicated that in the upper T'dtpunkt the Pump membrane 3 is the distance a between an extension Y the outer surface of the truncated cone forming the connecting rod head 5 towards the top and the surface 4a of the fastening disc 4 is slightly less than the thickness A of the non-tensioned membrane and that the fastening disk 4 is at a distance s from the conveying chamber wall corresponding to this deviation from the membrane thickness 14 has. This small distance s of the fastening disk 4 from the wall 14 is due to the manufacturing tolerances, the bearing play of the connecting rod 2 and the pivoting movement are coordinated in such a way that that if the distance S is as small as possible, contact between disk 4 and andung14 is still avoided.

In the exemplary embodiment it is provided that the outer edge R of the connecting rod head 5 is close to the clamping area the diaphragm 3 rticht and that the connecting rod 2 is not too large The stroke has a length such that the membrane 3 is compressed in the area of this outer edge R of the connecting rod head 5 is below the permissible value for the respective membrane material. When entering or exiting top dead center can namely through the pivoting movement of the connecting rod

slight compression of the membrane 3 take place. Turch a relatively flat angle and a sufficient one However, when the connecting rod 2 is long, squeezing of the membrane is avoided. The outer edge R of the connecting rod head 5 may also be slightly rounded.

In FIG. 1 it is shown in dashed lines that the mouth 15 the supply line leading from the suction valve 12 to the delivery chamber 16 arranged for closing by means of the membrane 3 in the connecting rod oscillation plane near that clamping point of the membrane can be, at which this is first raised in a connecting rod movement proceeding according to the arrow Pf1 or to the plant comes. When the diaphragm pump 1 is put into operation to generate a vacuum and the connecting rod 2 moves in the direction of the arrow Pf1 moves, namely between the membrane 3 and the intermediate cover 7 is initially reduced in size, so that there is an overpressure. This will make that Medium located in the pump room is pressed through the outlet valve 13. When this movement is complete, there is the connecting rod and the membrane according to FIG. 1 at top dead center. During the subsequent downward movement of the connecting rod 2 and the diaphragm 3, a negative pressure is created in the delivery space, through which the suction valve 12 is opened and the medium to be sucked in enters the delivery space is drawn into it. In the initial stage of the now beginning Verdräigiungshubes not only closes that Suction valve 12 but the membrane 3 is already very blocked

Early on, the mouth 15 is shown in dashed lines Feed line 16. "This ensures that the further pressure increase in the pumping chamber no longer affects that of the feed line 16 formed space. It will . This means that this space in front of the suction valve is also switched off as a dead space. It is particularly advantageous that the diaphragm 3 due to the angle relationships chosen according to the innovation comes to rest particularly well on the wall H having the mouth 15.

In particular through the combination of some or all of the aforementioned and features shown in the drawing, a diaphragm pump that is easy to manufacture is obtained with very little Dead space, which makes this pump particularly suitable for generating a vacuum.

Claims (8)

Schuti claims 1. Diaphragm pump especially for vacuum generation, which has a diaphragm clamped at the edges, deflectable by a connecting rod, which is attached to the upper about ^
side of a / piTz-like head of the connecting rod is fastened by means of a disk engaging in the conveying chamber, characterized in that the conveying chamber, the top of the connecting rod head (5) and the fastening disk (4) each as a cone or truncated cone or the like. are designed and have the same base angle (3d) between their lateral surfaces and their base surfaces, the opening (14) of the conveying chamber being designed as a hollow cone or truncated cone, and that at the top dead center of the membrane (3) the distance (A) from the outer surface (5a) of the connecting rod head (5) to the outer surface (14) of the pumping chamber is equal to the thickness of the membrane (3) and that the outer surface (4a) of the body forming the Befectigungsscheibe (4) in the upper dead point is approximately in the upper Surface (3a) of the deflected membrane (3) continues. 2. Pump according to claim 1, characterized in that the Base angle ([X) and the diameter (D) of the membrane, the Be ^ es + i panrsscheibe b ^ w. the flat support surface (5b) on the connecting rod head (5) and the connecting rod stroke (H) are coordinated in such a way that the permissible elongation of the Membrane material is not exceeded in the outer end positions. 3. Pump according to claim 1 or 2, that the base angle () is about 10 ° to 25 °. 4. Pump according to claim 1 or 2, characterized in that that at the top dead center of the pump diaphragm the distance (a) between an extension (V) of the outer surface (5a) of the truncated cone forming the connecting rod head (5) towards the top and the surface (4a) of the fastening washer (4) somewhat less than the thickness (A) of the not tensioned membrane (3) and that the fastening disc (4) one of these deviations from the membrane thickness yony
corresponding distance (s) / öer conveying chamber wall. 5. Pump according to claims 1 to 4> characterized in that that the small distance (S) of the fastening washer (4) from the wall (14) of the pumping chamber in the top dead center to the bearing play and the pivoting movement of the connecting rod (2) is matched. 6. Pu-npe according to one or more of claims 1 to 5, characterized in that the outer edge (R) of the connecting rod " ¹ - head (5) close to the clamping area the membrane (3) and that there the connecting rod (2) has such a length that a compression the membrane (3) in the area of this outer edge (R) of the connecting rod head (5) below the for the respective Diaphragm material permissible value. 7. Pump according to claim 6, characterized in that the outer edge (R) of the connecting rod head (5) is slightly rounded. 8. Pump according to one or more of claims 1 to 7, characterized in that the mouth (15) of a suction valve (12) or the like. Supply line (16) leading to the conveying chamber to be closed by means of the membrane (3) in the connecting rod oscillation plane close to the clamping point of the membrane (3) where it is first raised is or comes to the plant. Patent attorney