DE9218134U1 - CONTROL VALVE ARRANGEMENT - Google Patents

Description

22138M30893G1 - 7 -

Fig.2 a second embodiment of the control valve arrangement according to the innovation in which it is installed at an angle deviating from the vertical; and

Fig.3 shows an embodiment of the prior art.

Fig. 1 shows a first embodiment of a control valve arrangement according to the innovation. This essentially has a housing 1, a support body 20, a check valve 3 and a safety valve 5. The support body 20 has a central bore 22. The check valve 3 is inserted into the support body 20 from the lower side, while the safety valve 5 is inserted into the support body 20 from the upper side, so that the two valves 3, 5 are arranged axially aligned with one another. The check valve 3, the safety valve 5 and the support body 20 together form a structural unit which is screwed vertically into a corresponding thread of the housing 1 by means of a thread 19 on the support body 20. In order to seal the support body 20 from the housing 1, a sealing ring is attached to the shoulder-side end of the thread 19. The housing 1 is screwed into a fresh water pipe 6 using two union nuts 8, 9. This fresh water pipe 6 has an inlet 10 for fresh water and an outlet 11. A boiler is generally connected to the outlet 11, but this has not been shown here for the sake of better clarity.

Both the check valve 3 and the safety valve 5 are known in terms of their functionality, so that only their most important features and differences to known designs will be discussed here.

The check valve 3 essentially consists of a valve body 30 and a sealing body 31.

The valve body 30 has a cylindrical blind bore 41 on its rear side. On its front part, a valve body

Rege!venti!arrangement

The innovation relates to a control valve arrangement according to the preamble of claim 1.

Such control valve arrangements are mainly used in domestic water systems. There they are generally installed in a fresh water supply line, which supplies the boiler with fresh water. Such a control valve arrangement essentially consists of a housing with a check valve and safety valve arranged in it. The two valves are functionally connected in series in such a way that the safety valve is arranged behind the check valve in the direction of flow of the fresh water. The task of the check valve is to prevent water from the boiler from flowing back into the fresh water supply line. The safety valve, which is functionally closer to the boiler, ensures that the water expanding as the boiler heats up does not exceed a certain limit pressure that can be set on the safety valve, and that the safety of such a system is thus guaranteed.

Known embodiments of such control valve arrangements are designed in such a way that the part of the housing in which the check valve is arranged is designed as a pipe intermediate piece and that this part is installed in the fresh water connection line of the boiler. This part of the housing has a radial outlet from which a T-shaped branch line branches off. The safety valve arrangement is then inserted into this branch line from above, while an outlet is axially aligned downwards through which water under excessive pressure and drained from the safety valve arrangement can flow away.

Such a design of a control valve arrangement brings with it some disadvantages:

The space requirement is large.

If the check valve is defective, the entire housing with the valves arranged in it must be removed from the fresh water supply line. This is very time-consuming and results in a correspondingly long water interruption period.

The individual components of the check valve and the safety valve are not interchangeable, so that if one component is defective, the check valve or the safety valve or even both together must be replaced, which of course entails correspondingly high costs.

The aim of the innovation is therefore to design a control valve arrangement in such a way that it can be replaced or repaired more easily and in less time by allowing the check valve and the safety valve to be removed and reinserted together from the outside of the valve arrangement housing, and by optimizing or reducing the space required by the control valve arrangement.

This object is achieved by the features set out in the characterizing part of claim 1.

Further advantageous embodiments of the control valve arrangement are described in the dependent claims 2 to 10.

The axially aligned arrangement of the check valve and the safety valve together in one unit allows the space requirement of such a control valve arrangement to be optimized. This type of design also has the advantage that no branch line is required for the safety valve.

A preferred embodiment of the control valve arrangement provides that both the check valve and the safety valve are attached to a central support body, which also has a corresponding fastening thread. By means of this

This thread allows both valves to be attached to a corresponding thread on the housing. This type of design has the great advantage that the two valves can be removed or replaced very quickly and easily.

Another embodiment of the control valve arrangement provides an auxiliary body. In the preferred embodiment of this auxiliary body, it is provided that it has a tubular extension facing the safety valve, which has an end face designed as a sealing surface for its valve body, and which further has a tubular extension facing away from the safety valve, the cylindrical outer surface of which is simultaneously designed as a guide for the valve body of the check valve. Since this auxiliary body thus combines two important functions, it is preferably screwed into the support body so that it can be easily replaced or cleaned.

In a further embodiment, both the check valve and the sealing body of the safety valve are fastened to the support frame by means of threads.

The modular design of the control valve arrangement makes it possible to remove it easily and then dismantle it. This makes it possible to replace or clean defective components in an economical way and thus ensure that the control valve arrangement functions properly over a long period of time. In the following, an example of the state of the art and two examples of the innovation are explained in more detail using the attached drawings. The drawings show:

Fig.l shows a first embodiment of the control valve arrangement according to the innovation, in which it is installed vertically;

22138U30893G1 - 7 -

Fig.2 a second embodiment of the control valve arrangement according to the innovation in which it is installed at an angle deviating from the vertical; and

Fig.3 shows an embodiment of the prior art.

Fig. 1 shows a first embodiment of a control valve arrangement according to the innovation. This essentially has a housing 1, a support body 20, a check valve 3 and a safety valve 5. The support body 20 has a central bore 22. The check valve 3 is inserted into the support body 20 from the lower side, while the safety valve 5 is inserted into the support body 20 from the upper side, so that the two valves 3, 5 are arranged axially aligned with one another. The check valve 3, the safety valve 5 and the support body 20 together form a structural unit which is screwed vertically into a corresponding thread of the housing 1 by means of a thread 19 on the support body 20. In order to seal the support body 20 from the housing 1, a sealing ring is attached to the shoulder-side end of the thread 19. The housing 1 is screwed into a fresh water pipe 6 using two union nuts 8, 9. This fresh water pipe 6 has an inlet 10 for fresh water and an outlet 11. A boiler is generally connected to the outlet 11, but this has not been shown here for the sake of better clarity.

Both the check valve 3 and the safety valve 5 are known in terms of their functionality, so that only their most important features and differences to known designs will be discussed here.

The check valve 3 essentially consists of a valve body 30 and a sealing body 31.

The valve body 30 has a cylindrical blind bore 41 on its rear side. On its front part, a valve body

30, a sealing lip 34 is provided, which is fixed in position by means of a cap 36. The cap 36 is in turn fixed by a screw 37, which is screwed to a nut 38 inserted in the blind hole 41. The sealing body is screwed into a corresponding thread of the support body 20 by means of a thread 44. In order to seal the sealing body 31 and the support body 20 against the housing 1, sealing rings 42, 43 are provided, which surround the sealing body 31 and the support body in annular grooves at their lower ends. The sealing body 31 also has radial channels 40 and a lower, internal and beveled sealing surface 33.

The safety valve 5 essentially consists of the actual valve body 50 which is attached to a valve rod 54 and is guided by it. The plate-shaped valve body 50 has a sealing ring 52 on its underside. The valve body 50 is pre-tensioned by a spring 55 acting on the valve rod 54. This spring 55 is supported on a plate 58. This plate 58 has a thread by means of which it is attached in a housing 51 surrounding the safety valve 5 and by means of which it can be adjusted in its vertical position, so that the pre-tension of the spring 55 and thus of the valve body 50 can be adjusted. In addition, a sealing disk 57 is provided at the lower end of the safety valve housing 51 to seal the safety valve 5 against the housing 1.

Between the check valve 3 and the safety valve 5, an auxiliary body 23 is screwed into the support body 20 by means of a thread 18. In order to seal this auxiliary body 23 against the support body 20, the auxiliary body 23 has a sealing ring on the shoulder-side end of the thread 18. Furthermore, this auxiliary body 23 has a tubular extension 24, 25 on each of its front sides in relation to a longitudinal central axis 7 leading through the structural unit. The lower extension 25 is designed in such a way that its cylindrical outer surface 27 corresponds in shape and position to the blind bore 41 of the valve body 30 and thus

by serving as a guide. In this extension 25, a spring 29 is also supported, by means of which the valve body 30 is pre-tensioned. The upper extension 24 of the auxiliary body 23 is designed in such a way that its front surface 26 corresponds in shape and position to the valve body 50 of the safety valve 5, so that the sealing ring 52 of the valve body 50 lies flat and a corresponding seal is created.

In the housing 1 there is an inlet chamber 13, an outlet chamber 14 and a return flow chamber 15. Between the inlet chamber 13 and the outlet chamber 14 there is a first passage 46 and between the outlet chamber 14 and the return flow chamber 15 there is a second passage 47. In the area of the passage 46 the check valve 3 is functionally arranged and in the area of the passage 47 the safety valve 5 is arranged.

In order to be able to check the safety and functionality of the two valves 3, 5, two inspection ports 17 are provided in the housing 1.

To explain the functionality of the entire control valve arrangement, it is assumed that it is not yet exposed to water and that the boiler (not shown) is empty.

The fresh water flowing in via the inlet 10 first reaches the inlet chamber 13. From the inlet chamber 13, the water flows via the check valve 3 into the outlet chamber 14, since the safety valve 5 is closed in the resting state. From this outlet chamber 14, the water can finally reach a boiler (not shown) via the outlet 11. As soon as the pressure in the inlet chamber 13 is approximately the same (boiler full) as in the outlet chamber 14, the valve body 30 of the check valve 3 is moved downwards by the spring preload. As a result, the valve body 30 closes off the first passage 46 by means of the sealing lip 34 which now rests on the sealing surface 33 of the sealing body 31. If the boiler is now heated up, the water in it expands. This increases the pressure of the water

accordingly, so that there is a higher pressure in the outlet chamber 14 than in the inlet chamber 13.

The check valve 3 prevents the pressure between the two chambers 13, 14 from equalizing, since the valve body 30 of the check valve 3, which is subjected to the higher pressure on its rear side, now closes the first passage 46 with a force that increases approximately proportionally to the pressure difference. However, if the pressure prevailing in the outlet chamber 14 exceeds a certain limit value, the safety valve 5 comes into action. The valve body 50 of the safety valve 5 is subjected to the pressure prevailing in the outlet chamber 14 via the radial channels 21 of the support body 20 and the auxiliary body 23. As soon as the force set on the valve body 50 of the safety valve 5 by means of the preload spring 55 is exceeded, the valve body 50 moves upwards. This allows the water to flow out of the upper extension 24 of the auxiliary body 23 into the return chamber 15, thereby reducing the pressure in the outlet chamber 14.

Since both the check valve 3 and the safety valve 5 are subject to a certain amount of wear, it is important that the two valves 3, 5 can be replaced quickly and easily in the event of a defect, damage or the like. This is the case with the present design, since the entire assembly is fastened in the housing 1 by means of a thread 19 on the support body 20. This means that the entire assembly can be easily replaced, even by a layperson. Since all essential components are also fastened by screw connections, the removed assembly can be dismantled in the simplest way, the defective or damaged components replaced and the assembly reinstalled accordingly.

Fig. 2 shows a variant of the control valve arrangement. The entire structural unit of the control valve arrangement is identical to that in Fig. 1. The difference between this design and the previous one is

22138U3O893G1 .1 -

in the design of the housing 101 and in the installation position of the control valve arrangement. The housing 101 in turn has an inlet chamber 113, an outlet chamber 114 and a return flow chamber 115. Between the inlet chamber 113 and the outlet chamber 114 there is a first passage 106 and between the outlet chamber 114 and the return flow chamber 115 there is a second passage 107. As can be seen from this illustration, the structural unit formed from the check valve 3, the safety valve 5 and the support body 20 is inserted into the housing 101 at an angle deviating from the vertical, in this case approximately 45°. For this purpose, the housing 101 has a flange 102 protruding by 45° from the longitudinal center axis of the housing, in which the structural unit can be fastened by means of the thread 19 present on the support frame 20. The inlet chamber 113 has a curvature towards the top so that its upper inner surface 104 comes to rest on the sealing frame 31 of the check valve 3.

The compact design of such a control valve arrangement is particularly clearly visible in this illustration.

For comparison, Fig. 3 shows a control valve arrangement representing the state of the art. This control valve arrangement has a two-part housing 71, 72. The check valve 74 is housed in the main housing 71, while the safety valve 76 is arranged in the branch housing 72. The branch housing 72 has a radial housing extension 73 which is screwed into the main housing 71. The main housing 71 is screwed into a fresh water line 78 using two union nuts 80, 81. From this illustration it can be seen that if there is a defect in the check valve 75, or in order to clean it, the entire control valve arrangement must be removed from the fresh water line 78. This is of course associated with a correspondingly large amount of effort and is hardly feasible for a layperson. It can also be seen from the illustration that individual parts can hardly be replaced, or only with great effort.

Claims (1)

Protection claims 1. Control valve arrangement, in particular for use in domestic water systems, which has a housing (1, 101) with a check valve (3) functionally arranged therein and a safety valve (5) functionally arranged therein, characterized in that the check valve (5) and the safety valve (3) are arranged axially aligned one behind the other and are combined to form a common structural unit which is detachably inserted into the housing (1, 101) from the outside. 2. Control valve arrangement according to claim 1, characterized in that the structural unit has a support body (20) into which on one side the check valve (3) and on the other side the safety valve (5) are inserted. 3. Control valve arrangement according to claim 1 or 2, wherein the housing has an inlet chamber (13, 113), an outlet chamber (14, 114) and a return flow chamber (15, 115), and wherein there is a first passage (46, 106) between the inlet chamber (13, 113) and the outlet chamber (14, 114) and a second passage (47, 107) between the outlet chamber (14, 114) and the return flow chamber (15, 115), characterized in that the structural unit formed from the support body (20), the check valve (3) and the safety valve (5) is inserted into the housing (1) in such a way that the first passage (46, 106) can be closed by the check valve (3) and the second passage (47, 107) can be closed by the safety valve (5). 4. Control valve arrangement according to claim 2 or 3, characterized in that the support body (20) has a central bore (22) from which, relative to its longitudinal center axis (7), radial outlets (21) extend, through which water drained from the safety valve (5) can escape. 9. Control valve arrangement according to one of claims 2 to 8, characterized in that the support body (20) has an external thread (19) by means of which the structural unit can be fastened in the housing (1). 10. Control valve arrangement according to claim 5, characterized in that the auxiliary body (23) has a thread between the one extension (25) and the radial channels (28), by means of which it is screwed into a corresponding thread (18) of the support body (20).