DE3121053C2 - Method and device for carrying out the method for a membrane pump to prevent overstretching of the membrane - Google Patents

Abstract

The invention relates to a method for a diaphragm pump to prevent overstretching of the diaphragm and is preferably applicable to a hose diaphragm pump in which the primary working medium acts on a tubular hose diaphragm inside. The method and the device for carrying out the method ensure that if the suction side interrupts the delivery of the secondary medium, the primary working medium is not sucked in from the reservoir via the catch-up valve during each suction stroke and is fed into the pump chamber during the pressure stroke, which causes an overstretching of the hose membrane and finally their destruction can be effected. This is achieved by the fact that when the supply of the secondary medium is interrupted on the suction side, the secondary medium remaining in the diaphragm pump is automatically ventilated or gassed, with the secondary system negative pressure controlling the ventilation or gassing in the suction phase being lower than the primary side, the household of primary working medium is the system negative pressure that controls normal operation. The device for carrying out the method provides that between a suction valve and a shut-off valve or interruption point, a ventilation or gassing pipe opens into a suction line which is provided at its other end with a ventilation or gassing valve.

Description

;. ' it is ensured that the valve only a slight, is effective in response Schnüffelfe for the membrane harmless f \ Liehe pressure difference.
H ₁ This known arrangement is also not suitable for preventing diaphragm overstretching in the event of a disturbance or atypical (S see operating case in diaphragm pumps of the genus marked Ii in the introduction, since the ■ f pressure limitation of the primary working medium by sniffing from a storage tank is always added;, ; resulting in that with blocked membrane, the primary side of the pump during the suction stroke of the piston is filled with primary working medium during the subsequent;:. pressure stroke of the piston leads, this excess either ■; ': of an additional expansion of the membrane or, but ^it! is - with the appropriate setting of a: ί pressure relief valve on the primary side of the pump - the entire excess quantity via this pressure ' also usually leads to excessive heating of the primary% working medium or the entire diaphragm pump.
It is the object of the present invention to further develop the known method for operating the known diaphragm pump in such a way that the with: '; the interference or atypical operating said case resulting danger of overstretching of the diaphragm is captured Moreover, the known diaphragm pump 'by a device for carrying out the inventions ^should: to the invention method will be further developed.

This object is achieved in that in suction-side \: ger interruption of the promotion of secondary Me-M diums (incident or atypical operating case), an automatic ventilation or aeration of the remaining in the secondary diaphragm pump medium takes place, WO; in the case of the aeration or gassing in the suction phase:, '. system negative pressure on the secondary side is less than '■■ the primary side system negative pressure controlling the household of the primary working medium in normal operation.

The proposed method ensures that if the supply of the secondary medium is interrupted on the suction side, the primary working medium is not sucked in from the storage container via the catch-up valve during each suction stroke and is pumped into the pump chamber during the pressure stroke. A steady increase in the volume of primary working medium located within the hose membrane leads to an overstretching of the hose membrane and ultimately to its destruction. By contrast, the proposed method ensures that the system negative pressure which controls the household of the primary working medium in normal operation and which opens the catch-up valve is not even reached in the event of a malfunction or atypical operation. This can be achieved effectively through automatic ventilation or gassing of the secondary medium remaining in the diaphragm pump. The device for carrying out the method provides that between a suction valve and a shut-off valve or interruption point, a ventilation or gassing pipe opens into a suction line, which is provided at its other end with a ventilation or gassing valve whose response vacuum is lower than the response vacuum of a catch-up valve , which is arranged in a connecting line of a connection between a storage container and a primary-side power unit.
The proposed aeration or gassing valve, when appropriately adjusted with respect to the catch-up valve, ensures in a simple and effective way that a dangerous negative pressure formation within the secondary medium remaining in the diaphragm pump is prevented.

The method according to the invention and the device for performing the method should be based on 1 and 2 of the drawing will be explained. It shows

to F i g. 1 is a schematic center section through a hose diaphragm pump of the generic type and

F i g. 2 shows a central section through a ventilation or gassing valve for carrying out the invention Procedure.

According to FIG. 1, the hose diaphragm pump shown schematically consists of the preferably spherical diaphragm housing 1 with its suction and pressure connection la or \ b at right angles to the line of symmetry defined by the suction and pressure connection la or 16, in the middle of the diaphragm housing 1 is a support tube provided with a passage opening 3a 3 arranged which is surrounded concentrically by the hose membranes 2, 2 a. The tubular membrane 2, la are respectively clamped at their ends the diaphragm casing. 1 Its interior is connected via the passage opening 1c in the diaphragm housing 1 to the housing of the power section 4, which accommodates a piston 5 that is preferably moved in an oscillating manner.

The suction port la is upstream the suction valve 6 and the pressure port 1 b is the pressure downstream of valve 6a via a connecting line 46 in the terminal 4a of the housing of the power section 4 is connected to a reservoir 7 for primary working medium. 9 The connecting line 46 is controlled via a make-up valve 8 which is known per se in its structure and consists of a closing element 8a, a spring 86 and a loss hole 8c. In normal operation, the catch-up valve 8 opens when the primary-side system negative pressure p _{ux is set} , so that the primary working medium 9 can flow from the reservoir 7 into the housing of the power unit 4 during the suction stroke of the hose diaphragm pump. During the pressure stroke of the hose diaphragm pump, a small amount of the primary-side working medium is lost again into the reservoir 7 via the loss bore 8c of the catch-up valve 8. During the subsequent suction stroke of the hose diaphragm pump, due to the lack of primary working medium, hose diaphragms 2, 2a first come to rest on support tube 3 before catching-up valve 8 opens and supplies the missing primary working medium from reservoir 7. The flow directions of the primary-side and secondary-side medium 9, 10 are indicated in the suction phase by the arrows labeled S and in the pressure phase by the arrows labeled D.

It is now assumed that the conveyance of the secondary medium 10 is interrupted by clogging or closing of the shut-off valve 11 within the suction line 14. Without the method proposed according to the invention, primary working medium 9 would now be sucked into the housing of the power unit 4 via the catch-up valve 8 with each suction stroke S in an increased amount compared to normal operation, since the contraction of the hose membrane 2, 2a that occurs during normal operation is absent the promotion of the secondary medium 10 via the suction line 14 is not possible.

During the pressure stroke D , the steadily increasing volume of the primary working medium 9 leads to an expansion and ultimately to the destruction of the hose membrane 2, 2a. A possible diaphragm overstretching shortly before the diaphragm is destroyed is approximately indicated on the suction side by the dash-dotted hose diaphragm contour Fs and on the pressure side by the correspondingly illustrated hose diaphragm contour Fd. If an arranged in the storage container 7, shown in FIG. 1, empty probe, not shown, signals a malfunction before the hose membrane 2, 2a is destroyed, there is in principle still the possibility of stopping the membrane pump.

The proposed method now provides for the secondary medium 10 remaining in the diaphragm pump to be automatically aerated or gassed in the event of a malfunction or atypical operation, so that an accumulation of the primary working medium 9 within the pump chamber P is avoided and thus an overstretching and destruction of the hose diaphragm 2, 2a is prevented (suction phase 5 ').

The device for carrying out the method according to the invention provides that a ventilation or gassing pipe 12 opens into the suction line 14 between the suction valve 6 and the shut-off valve 11 'or the interruption point in the suction line 14. At the other end of the ventilation or gas supply pipe 12 is a ventilation or gas supply valve 13, known per se in its structure, consisting of a valve housing 13a, a closing element 13Z>, a seat seal 13c, an upper spring abutment Md, a lower spring abutment 13e, passage openings 13 /; a biasing device 13 # a spring 13 /? and a cap 13 / provided, the adjustable negative response pressure Pu _{2 is} less than the response negative pressure ρ ,,, of the catch-up valve 8.

The constant ventilation of the secondary medium 10 prevents the catch-up valve 8 from opening, so that in the initial phase of the process, as long as the housing of the power unit 4 is completely filled with the primary working medium 9, only the primary working medium 9 is lost through the leakage hole 8c of the catch-up valve 8 greater loss of primary working medium 9, the change in volume caused by the piston 5 within the hose diaphragm 2, 2a as a result of the air or gas content in the secondary medium 10 and as a result of the only incompletely filled housing of the power unit 4 hardly changes the shape of the hose diaphragm 2 , 2a off. Overstretching of the diaphragm or destruction of the diaphragm is impossible, even if the hose diaphragm pump is operated continuously.

1 sheet of drawings

55

Claims (2)

1 2 tion according to the preamble of the main claim and PatentansDi-üche- ^a device for carrying out the method. ^v ' In the case of the membrane pump, which is known in its design, I. Method for a membrane pump to prevent which according to a known method of operation is "St one of ^ the secondary medium throughput the same sense of volume reduction of the pumping trömten part which, for -Rohrieitung dL · Rat as an integral part in an enclosed their working medium to be pumped by eigengesetzl secondary medi- before Kontraktionsgeschwind.gke.t .rkt, can be used under AusuTe and is provided on the suction and pressure side with each exertion of pressure on the working medium nachvoUzo-Sem non-return valve, with an as, 5 gen, so that the pressure of the primary separate unit formed power section, wel- beirsmedmms is always greater than that of the pump to be pumped with the pump part via a primary flowing secondary medium, it is ensured that in every capable working medium the connection arm phase of the suction stroke of the diaphragm pump is coupled to the pressure door, the primary The working medium of the primary working medium is always larger than that of a tubular formed, made of elastomeric 20 of the secondary medium to be pumped s, so that the existing membrane, which has the shape of a membrane defect and contamination of the pnmacylindrical hose, hits within the working medium through the secondary to be pumped and this is excluded by a pulsating pressure medium actuated and the secondary medium in one of the The known diaphragm pump and the known The membrane surrounding the pump chamber is located, however, does not ensure that in the process and with one known per se, the household of the following sturgeon or atypical Betr.ebs-Drimärem The catching-up event that controls the working medium prevents overstretching of the membrane. This til that in the suction phase of the diaphragm pump in Ab- Stör- or. An atypical operating case is given when there is a nuisance from the primary-side system negative pressure this occurs occasionally in practice - the primary suction Working medium from a reservoir 30-term promotion temporarily interrupted without can flow into the power section and in which the diaphragm pump is stopped at the same time. the Pressure phase of the diaphragm pump a small amount of interruption can be achieved by closing a suction side ge primary working medium via a shut-off valve arranged with loss drilling or through a total releases into the storage container, thereby causing blockage of the suction line, k e η η ζ e i c h η e t that in the event of a suction-side interruption, it is known from DE-OS 24 02 056, in the case of a KoI-chung the delivery of the secondary medium ben-diaphragm pump the negative pressure of the pnmären (Incident or atypical operating case) an automatic working medium at the end of the suction stroke by Belufge Limit ventilation or gassing of the primary working medium in the diaphragm, The secondary medium remaining in the pump takes place, This measure causes cavitation of the the disruptive gas extraction caused by ventilation or primary working medium in the suction phase Controlling secondary system under- see and membrane damage avoided. An overpressure smaller than the primary side, the budget on supply of the known measure on diaphragm pumps primary working medium in normal operation, the introductory marked type can be used in the preceding System negative pressure is the malfunction or atypical operating case mentioned above 2 device for performing the method 45 do not prevent membrane overstretching, since the neighboring Claim 1, characterized in that the ventilation of the primary working medium was only known on The end of the suction stroke starts after the piston opens 21 between a suction valve (6) and a path to its rear end position via a non-blocking flap or interruption point (ll, ll ') The catch-up valve provided the primary working medium lost during the pressure stroke via a 2 2 a ventilation or gas supply pipe (12) into a 50 loss bore to the suction line (14) opens, which one sucks in next. As in the event of a fault or atypical operation 23 at its other end with a ventilation the membrane more or less m their movement or gas valve (13), which is blocked, is also used during the suction 2 31 response pressure (secondary system movement of the piston, additional primary working medium pressure in the suction phase of the disturbance or atypical 55 um sucked in via the catch-up valve the speech negative pressure (primary-side system under- degree of the diaphragm blockage and the response pressure in the suction phase of normal operation) pressure of the ventilation valve is dependent, leads to jep _u1 a catch-up valve (8), the pressure stroke to an additional expansion of the 24 in a connecting line (4b) of an An 60 membrane and finally to its destruction. Closure (4a) between a storage tank From DE-GM 74 20 466 a membrane (7) and a primary-side power part (4) is known, in which the primary side (hydraulic chamber) is arranged by the arrangement of a sniffer valve Diaphragm pump from a controllable pressure 65 standing reservoir can be supplied with primary working medium (hydraulic fluid) if The invention relates to a method for a membrane that occurs during the suction stroke of the membrane Branch pump to prevent the diaphragm excess pressure from falling below a certain value. As a result |