NO135399B - - Google Patents

Description

Device for mixing disinfectant or similar additives into a water stream.

The invention relates to a device

for mixing disinfectants or similar additives into a stream of water in metered quantities. In the case of known devices of this type, the disinfecting agent for use is the pressurized water

using the aperture pressure effect. As soon as no more disinfection solution is taken out at the consumer points, the effective pressure becomes zero and the mixing of concentrate then forcibly ceases. However, the connection from the concentrate tank to the pressurized water line remains

standing open above the dosing nozzle, so that it may happen that the water 1 the valve returns to the concentrate container and dilutes the disinfection concentrate. At the next application, a lower concentration than prescribed will then occur. A correct dosage is only possible with such devices, when the full effective pressure that sets in when the solution is consumed becomes effective at the dosing nozzle, i.e. when only a precisely determined drop step exists at the dosing nozzle. If, in order to avoid dilution of the disinfectant concentrate by water flowing back into the container, a normal spring-loaded shut-off valve was to be connected in the concentrate line, this would result in a

further uncontrollable drop step, so that the dosing accuracy would be disturbed. At the inherently small operating pressures, which are common with dosing devices, already make a small change

of the pressure before the dosing nozzle changes

partially noted. The purpose of the invention is to avoid this disadvantage.

According to the invention, a membrane non-return valve is arranged in the connecting line between the disinfectant or additive container and the water supply line, which prevents backflow of water into the disinfectant or additive container and whose closing joint is combined with the dosing nozzle that determines the degree of mixing to a coherent body that is in tension

in the moving membrane center. On this

way the membrane now separates the whole

pressure drop and it is moved by this pressure drop into the open position, so that the road roller seat and the vemtil plate are raised apart from each other.

The total ventilation pressure figure then works in the dosing nozzle.

The drawing shows an embodiment of the object of the invention.

Fig. 1 schematically shows a device according to the invention in a vertical section, seen from the side, and

Follow 2 shows a diaphragm non-return valve according to the invention in a vertical section, seen from the side.

In fig. 1, 1 is a pressure vessel, which is divided into two parts by means of a memtor bag 2. The right part is filled with disinfectant. In the left part is the pressurized water, which puts the concentrate under pressure above the membrane bag. The pressurized water enters the container through the pressurized water line 3 and the connector 4. In the extension of the pressure pipe

3 is the mixing head 5 built-in, at the inlet of which there is a baffle. To the mixing head, the consumer tube 6 ends with shut-off spray nozzles 7 and 8. Through the line 9, the disinfectant enters the mixing head via the membrane two-way valve 10. A dosing nozzle 14 (fig. 2) in this membrane non-return valve ensures the correct measurement of the amount of disinfectant to be added to the water. As soon as the consumption lines 7 and/or 8 are opened, the aperture in front of the two-landing head 5 causes a pressure drop, under the influence of which the disinfectant flows through the dosing nozzle into the mixing head. As soon as the pre-use lines 7 and 8 are closed, there is no longer any pressure drop and the admixture stops. However, since the entire system is still under pressure, water over the dosing nozzle 14 could flow back to the part of the container 1 that contains the disinfectant and dilute the concentrate. To prevent this, the memtorantilfeake impact valve 10 (fig. 1) is connected to the line 9. According to fig. 2, this membrane check valve 10 consists of the membrane housing 11, in which the membrane 12 is clamped. In the middle of the diaphragm, the valve seat 13 of the additional stroke valve is clamped, which also has the dosing bore 14. The spring 15 presses the valve seat against the valve plate 16 and thus separates the connection from the upper to the lower diaphragm space. A return flow of the water to the dosing agent is thus interrupted. As soon as a consumer site is taken into account, occurs

the pressure drop at the diaphragm and the higher pressure above the diaphragm raises the valve seat 13 up from the valve plate 16, and it can

then flow desmf ection agent through the dosing nozzle 14 to the mixing head 5 (fig. 1). The total pressure drop is now always in the dosing nozzle 14 so that no dosing errors can occur.

Claims (2)

i 1. Device for mixing disinfectant or similar additives into a stream of water in metered quantities, characterized in that the 1 connection line (9) between the disinfectant or additive container (2) and the water supply line (3) is arranged a membrane impurity valve (10) which prevents the impurity of water in the disinfectant or additive container (2) and whose spring-loaded closing links (13) is combined with the dosing nozzle (14) which determines the degree of contact of a continuous body 1, which is clamped in the movable membrane member (12), so that the overall effective pressure drop is in the dosing nozzle. 2. Device according to claim 1, characterized in that the flow cross-sectional area of the non-return valve is several times larger than the dosing nozzle.