DE29823960U1 - Valve for hot water systems - Google Patents

Description

Metallwerke Neheim Goeke & Co. GmbH 10. Nov. 1999

To the Ruhrwiesen 3 76525219 DE

D-59755 Arnsberg/Neheim Hz/de

Valve for hot water systems

The present innovation relates to a valve according to the generic term of patent claim 1. Such a valve is known, for example, from DE-U 94 20 412 and is used for thermostatic regulation, shut-off and draining of drinking water circulation systems. The known valve allows the water temperature in drinking water circulation systems to be kept very reliably in the range of 55°C. In order to kill any legionella that may form in the system, an interval-based thermal disinfection of the system by increasing the water temperature to 70 ⁰ C or more has recently been required.

The present innovation aims to design the valve in such a way that such disinfection is possible.

This object is achieved according to the characterizing features of claim 1. Further advantageous embodiments of the valve according to the invention can be found in the dependent claims.

The innovation is described in more detail below using the only figure in the attached drawing.

According to this figure, opposing connection pieces 12 and 14 are formed on a housing 10 of a drinking water valve, which lead to the line or to the drinking water heater (boiler). An obliquely directed screw piece 16 serves to accommodate a screwed-in valve upper part 18. A valve seat 20 is formed inside the valve housing 10, against which a first closure piece 24 arranged on a hollow valve spindle 22 acts. In principle, the position of this first

The presetting for the flow is made by the connection of the closure piece 24 to the corresponding valve seat 20. The heating valve can be shut off using this first closure piece 24.

The hollow valve spindle, designated overall with the number 22, is made of two parts. The lower spindle section 22b is inserted into the upper spindle section 22a and held in place with a locking or snap connection. An elastic flat seal 26, which is made of an elastomer, for example, is inserted into a recess inside the upper spindle section 22a. When the snap or locking connection engages, the lower spindle section 22b engages with its front side in a sealing manner in this flat seal 26, which in turn secures the locking or snap connection in the axial direction due to its elastic restoring force.

This flat seal 26 extends into the interior of the two hollow spindle sections 22a, 22b. In the cavity of the lower spindle section 22b, a second closure piece 28 can be moved from the outside against the pressure of a return spring 30. This return spring 30 is supported with one end in the interior of the lower spindle section 22b. This second closure piece 28 is double-acting. When in the appropriate position due to the return spring 30, the upper end of the closure piece acts against the inwardly projecting flat seal 26.

An opposite closure piece end 32 of the second closure piece 28 projects outward through the lower spindle section 22b and, together with the projecting section, forms the contour of the first closure piece 24 and, together with the latter, determines the throttle gap.

An inserted draining device (not shown) acts on the upper end of the closure piece through the hollow space of the upper valve spindle section 22a. After the second closure piece 28 is lifted off the flat seal 26, water flows out of the line through the hollow valve spindle.

A screw cap 34 is mounted on a rotary drive at the end of the two-part valve spindle 22 protruding from the valve upper part 18. The presetting is carried out after removing the screw cap 34. The valve spindle 22 is not moved.

This is followed by a corresponding rotation of the display device, designated overall by the number 36.

A thermostat regulator 38 is placed on the hollow valve spindle 22 through a shoulder of the screw cap 34. A threaded connector provided on a housing 40 is screwed onto the external thread section of the upper spindle section 22a in a sealed manner. An expansion element 42 is accommodated in this thermostat housing 40, which can be moved against an overtravel spring 44. When the overtravel spring 44 acts alone, the expansion element 42 rests on the valve spindle 22 with a collar. A piston 46 of the expansion element 42 projects into the hollow valve spindle 22 or into its upper spindle section 22a and acts against a cylindrical hollow actuating member 48, which in turn rests with its open end against the second closure piece 28. The upper closed end of this actuating member 48 is guided in a limitedly movable manner in a limiting sleeve 50 which is fixed to the expansion element 42. The lower end of this limiting sleeve is drawn inwards so that in the end position the actuating member 48 strikes against this drawn-in end with an outer collar at the closed end. The actuating member 48 is guided in a plastic sliding bushing 52 and sealed with ring seals. The plastic sliding bushing 52 is inserted flush into a recess in the interior of the upper spindle section 22a.

Water penetrating through a cavity 54 in the second closure piece 28 reaches the actuating member 48 and heats the expansion element 42 via the piston 46, which lifts off accordingly against the stroke of the spring 44. The thermostat housing 40 is surrounded by a jacket 56 for insulation. The distance of the first closure piece 24 from the valve seat 20 on the housing side is determined via the thermostat regulator 38.

When the housing 40 of the thermostat regulator 38 is screwed on, the expansion element 42 rests with its collar on the upper valve spindle section 22a. This enables precise adjustment between the support edge and the end of the actuating element 48. When screwed on, the expansion element 42 slides slightly in the direction of the overtravel spring 44, so that manufacturing and screwing tolerances of the housing 40 have no influence on the temperature adjustment.

The task of the fitting described so far is to maintain the temperature in drinking water circulation systems very precisely and reliably in the range of 55 ⁰ C. If the temperature exceeds this, the valve throttles to a minimum flow. 5

In order to disinfect the entire plant system, there are regulations to periodically raise the temperature throughout the entire plant system to 70 ⁰ C and above.

To make this possible, a bypass 60 is molded onto the valve housing 10K according to the innovation. In the bypass 60, a further valve seat 62 is arranged, with which a further closure body 64 interacts. A further screw connection 66 is molded onto the valve housing 10, into which a further valve upper part 68 is inserted, which guides a valve spindle 70 connected to the closure body 64 in a sealed manner. According to the invention, this valve spindle 70 can now cooperate with a drive which consists of a manual drive 72, a thermal drive 74, an electric drive 76 or a radio-controlled drive 78. The use of a thermal drive consisting of a thermal control attachment which is set to a water temperature of 70 ⁰ C and opens the valve 62, 64 when this temperature is reached is particularly advantageous.

Claims (7)

1. Valve for hot water systems, in which a connection piece to the line, a connection piece to the consumer and a screw connection for receiving a valve upper part with a first closure piece arranged on a hollow valve spindle, which forms a throttle-like pre-setting for the flow with a valve seat in the housing, are provided on a housing, and in the hollow valve spindle a second hollow, double-acting valve closure piece which can be actuated from the outside against the pressure of a spring can be displaced from the outside relative to a corresponding valve seat in the valve spindle in order to empty a line via the valve spindle, wherein this second valve closure piece can be displaced with its end opposite the drain valve seat through the first valve closure piece in the direction of the housing valve seat, and wherein a thermostat regulator with its housing is screwed onto the valve spindle with an expansion element which acts against an overtravel spring and whose piston acts against the second closure piece, characterized in that on the valve housing ( 10 ) a bypass ( 60 ) is arranged around the valve seat ( 20 ), the passage of which can be controlled depending on the temperature. 2. Valve according to claim 1, characterized in that a further valve seat ( 62 ) cooperating with a closing body ( 64 ) is arranged in the bypass ( 60 ) and the closing body ( 64 ) is connected to a drive (70; 72-78). 3. Valve according to claim 2, characterized by a thermal control attachment ( 74 ) as drive. 4. Valve according to claim 2, characterized by an electric drive ( 76 ). 5. Valve according to claim 2, characterized by a radio-controlled drive ( 78 ). 6. Valve according to claim 2, characterized by a manual drive ( 72 ). 7. Valve according to claim 3, characterized in that the thermal control attachment is adjustable to a predeterminable actual temperature (70°C) in order to open the valve ( 62 , 64 ) at this temperature.