JP2017110808A - Thermostat mixing valve used in sanitary faucet - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a thermostat mixing valve including a thermostat element composed of shape memory alloy, suitable for standard positioning of a water inflow port and a hot water inflow port at a sanitary faucet having the water inflow port closer to an adjustment mechanism with respect to the hot water inflow port.SOLUTION: A position adjustment unit 2 includes a thermostat element 29 composed of shape memory alloy, the thermostat element is kept into contact with and connected to a linear stroke element 13 at a first supporting point 31, and an axial structural length of the thermostat element is changed to compensate fluctuation of mixed water temperature. A valve slider vertical position is adjusted by cancelling or applying preload of an energization spring 47 acting on a valve slider 19, the valve slider has a supporting base portion 37, the thermostat element is supported by the supporting base portion at a second supporting point, and the thermostat element is disposed between the position adjustment unit and the valve slider in an axial action direction.SELECTED DRAWING: Figure 1

Description

  The present invention relates to a thermostatic mixing valve for adjusting the temperature of mixed water in a sanitary faucet according to the superordinate concept of claim 1.

  In DE 102 2006 3018 A1 (DE 10 2006 032 018 A1), a thermostat mixing valve is known, which thermostat mixing valve usually comprises a thermostat cartridge having a thermostat element which is actually an extension element. Prepare. When the mixed water temperature fluctuates (based on fluctuations in the water supply amount or hot water supply amount in the fresh water supply network), the structural length in the axial direction of the thermostat element changes, whereby the mixed water temperature variation can be compensated. Since the above-mentioned extension element has a slow response characteristic, there is a possibility that excessive vibration may occur when compensating for the mixed water temperature fluctuation.

  In order to avoid such excessive vibration, a thermostatic mixing valve as described at the beginning is known from DE 102 2004 050 877 A1 (DE 10 2004 050 877 A1). The thermostat element is realized as a coil spring made of a shape memory alloy. Such a coil spring has a higher response sensitivity compared to the extension element described above, and this can reduce excessive vibrations when compensating for the mixed water temperature variation. In the following, the structure and functional form of a known thermostat mixing valve will be described in DE 102004050877. The thermostat mixing valve has a rotating grip as a position adjusting unit, and the rotating grip cooperates with a valve slider that can be adjusted in the raising / lowering position in the axial direction. A thermostat spring comprising a valve slider and a shape memory alloy is disposed in the cartridge housing inside the thermostat mixing valve. The cartridge housing is formed by a head portion and a valve seat for hot water. In this case, the linear stroke element of the position adjusting unit is guided through the penetration guide portion in the head portion until it comes into contact with the valve slider. Yes. The valve slider has a valve seat that protrudes radially outward, and the valve seat can be adjusted in the vertical direction in a recess formed in the cartridge housing over a predetermined axial stroke. A hot water adjustment gap closer to the position adjustment unit in the direction and a water adjustment gap closer to the position adjustment unit in the axial direction are formed.

  In the case of mixed water temperature fluctuations in which the mixed water temperature rises, the thermostat spring extends in the axial direction, and the flow cross section of the water adjustment gap expands and at the same time the flow cross section of the hot water adjustment gap decreases. Conversely, when the temperature of the mixed water decreases, the thermostat spring is compressed in the axial direction, and the flow cross section of the water adjustment gap is reduced, and at the same time, the flow cross section of the hot water adjustment gap is enlarged. Adjustment of the lift position of the valve slider to compensate for the mixed water temperature variation is performed by reducing or increasing the preload of the biasing spring acting on the valve slider.

  In DE 102004050877, the thermostat spring is supported between the hot water valve seat and the linear stroke element of the position adjusting unit, while the biasing spring is connected to the hot water valve seat. It is supported between the valve slider.

  In the above-described structure of the thermostat mixing valve, the hot water adjustment gap must be positioned closer to the position adjustment unit than the water adjustment gap in the axial direction. However, the positioning of the hot water adjustment gap and the water adjustment gap does not correspond to the supply conditions in a normal sanitary faucet in which the water inlet is positioned closer to the position adjusting unit instead of the hot water inlet. Thus, the thermostat mixing valve known from DE 102004050877 cannot be assembled in such a standard sanitary faucet.

  The object of the present invention is to provide a thermostat element made of a shape memory alloy adapted to the standard positioning of the water inlet and the hot water inlet in a sanitary faucet where the water inlet is located closer to the adjustment mechanism than the hot water inlet. The object is to provide a thermostatic mixing valve.

  This problem is solved by the configuration described in the characterizing portion of claim 1. Preferred refinements are disclosed in the dependent claims.

  According to the configuration described in the characterizing part of claim 1, the thermostat element is no longer supported between the positioning unit and the hot water valve seat, but rather between the positioning element and the valve slider. It is supported. Correspondingly, the thermostat element is supported by the linear stroke element of the position adjustment unit at the first support point and is supported by the valve slider at the second support point. The element is provided between the position adjustment unit and the valve slider in the axial direction of action. On the other hand, in DE 102004050877, the thermostat element is not provided between the position adjustment unit and the valve slider in the axial direction of action, but rather rather than the position adjustment unit. It is provided between the valve seat for hot water.

  In the technical implementation, not only the valve slider but also the thermostat element may be arranged in the cartridge housing of the thermostat cartridge of the thermostat mixing valve. The cartridge housing may be formed of a head portion and a valve seat for hot water. A penetrating guide may be formed in the head portion, through which the linear stroke element extends until it abuts the thermostat element. Furthermore, the biasing spring may be supported between the valve seat for hot water and the end surface of the valve slider as viewed in the axial direction. In contrast, German Offenlegungsschrift 102004050877 does not provide a biasing spring between the valve seat for the hot water and the end face of the valve slider, but directly with the adjusting mechanism (ie the thermostat element). Between the valve slider and the linear stroke element abuttingly coupled. According to a preferred technical construction, the thermostat element is a coil spring made of a shape memory alloy.

  The valve slider usually has a double valve seat that protrudes radially outward, and the double valve seat protrudes into a recess formed in the cartridge housing and is axially closer to the position adjustment unit. Water adjustment gap and a hot water adjustment gap on the side away from the position adjustment unit in the axial direction are formed. Therefore, when adjusting the lift position of the valve slider in the axial direction, the water adjustment gap may be enlarged and at the same time the flow cross section of the hot water adjustment gap may be reduced, or vice versa.

  In the structure according to the present invention, the water adjustment gap is positioned closer to the position adjustment unit than the hot water adjustment gap in the axial direction, unlike German Patent Application No. 102004050877. Such positioning of the hot water adjustment gap and the water adjustment gap corresponds to the supply conditions in a general sanitary faucet in which the water inlet is similarly positioned closer to the position adjusting unit than the hot water inlet. Therefore, the thermostat mixing valve according to the present invention can be easily assembled to such a standard sanitary faucet.

  With the above-described structure of the thermostat mixing valve, the mixed water temperature fluctuation can be compensated as follows. When the mixed water temperature rises, the thermostat spring expands in the axial direction, and at the same time, the flow cross section of the water adjustment gap expands and at the same time the flow cross section of the hot water adjustment gap decreases. Conversely, when the temperature of the mixed water decreases, the thermostat spring is compressed in the axial direction, and the flow cross section of the water adjustment gap is reduced, and at the same time, the flow cross section of the hot water adjustment gap is enlarged.

  According to one technical aspect, the support base configured on the linear stroke element with respect to the first support point of the thermostat element may be an annular shoulder integrally formed with the linear stroke element. The annular shoulder may preferably be located inside the cartridge housing.

  Furthermore, the linear stroke element of the position adjusting unit may be extended with a cylindrical guide part beyond the annular shoulder in the axial direction. The guide portion of the linear stroke element is arranged radially inside the sleeve-like valve slider, thereby forming an annular gap in which the thermostat spring is arranged.

  Preferred and / or improved aspects of the invention as set forth in the foregoing and / or dependent claims may be considered individually except in the case of, for example, unambiguous dependent or incompatible alternative aspects. Any combination can be applied.

  Hereinafter, the present invention, preferred embodiments and improved embodiments of the present invention, and advantages thereof will be described in detail with reference to the drawings.

It is sectional drawing of a thermostat mixing valve. It is a partial expanded sectional view of the thermostat spring assembled | attached to the thermostat mixing valve.

  FIG. 1 shows a thermostat mixing valve 1, which can be assembled to a sanitary faucet (not shown) used for, for example, a shower. In this embodiment, the thermostat mixing valve 1 includes a position adjustment unit 2 having an operation lever 3 that can be manually operated, and the temperature of the mixed water can be adjusted on the user side using the operation lever 3.

  The thermostat mixing valve 1 includes a thermostat cartridge 5, and the housing of the thermostat cartridge 5 is formed of a head member 7 and a valve seat 9 for hot water. The head member 7 of the thermostat cartridge 5 has a penetration guide 11 that opens upward in the axial direction, and the linear stroke element 13 of the position adjustment unit 2 is guided through the penetration guide 11. The linear stroke element 13 is drivingly coupled to the operation lever 3 via an overload unit 15 in the axially upward direction. The pivoting movement of the operating lever 3 is converted into an axial movement of the overload unit 15 via the thread engaging portion 16, and the overload unit 15 is elastically and flexibly supported by a pressing member 17. Accordingly, the linear stroke element 13 is pressed.

  In FIG. 1 or FIG. 2, the linear stroke element 13 extends to the inside of the thermostat cartridge 5 housing. A sleeve-like valve slider 19 is disposed in the cartridge housing, and the valve slider 19 has a double valve seat 21 (FIG. 2) protruding outward in the radial direction. The double valve seat 21 projects radially outwardly into a recess 22 (FIG. 2) formed in the cartridge housing 5, and is operated in the axial direction with a water adjustment gap 23 on the side closer to the operating lever 3 in the axial direction. A hot water adjustment gap 25 on the side away from the lever 3 is formed. Both adjustment gaps 23 and 25 are connected to the corresponding hot water inlet HW and water inlet CW of the sanitary faucet in the assembled state of the thermostat mixing valve.

  The water adjustment gap 23 and the hot water adjustment gap 25 communicate with the hollow cylindrical mixing water chamber 27 inward in the radial direction, and the sleeve-shaped valve slider 19 is positioned in the mixing water chamber 27 so that the elevation position can be adjusted. . As is further apparent from FIGS. 1 and 2, a thermostat spring 29 made of a shape memory alloy is interposed between the linear stroke element 13 and the valve slider 19. The thermostat spring 29 is supported on the annular shoulder 33 of the linear stroke element 13 by the upper support point 31 and supported by the inner shoulder 37 of the valve slider 19 by the lower support point 35. Has been. The linear stroke element 13 extends in the axial direction beyond the annular shoulder 33 with a cylindrical guide part 39, which is arranged radially inside the sleeve-like valve slider 19. Thus, an annular gap 41 (FIG. 2) in which the thermostat spring 29 is positioned is formed. A biasing spring 47 is interposed between the inner shoulder 43 of the hot water valve seat 9 and the axial end face 45 of the valve slider 19.

  The thermostat mixing valve 1 operates as follows when the mixed water temperature fluctuates (based on fluctuations in the water inflow amount or hot water inflow amount in the fresh water supply network). In the case of a mixed water temperature fluctuation in which the mixed water temperature rises, the thermostat spring 29 extends, and the flow cross section of the upper water adjustment gap 23 expands and at the same time the flow cross section of the lower hot water adjustment gap 25 decreases. . On the contrary, in the case of the mixed water temperature fluctuation in which the mixed water temperature decreases, the thermostat spring 29 is compressed in the axial direction, the water adjustment gap 23 is reduced, and the hot water adjustment gap 25 is enlarged at the same time.

  The linear stroke element 13, the thermostat spring 29, and the valve slider 19 form one motion connecting unit when the valve slider 19 is adjusted in the raising / lowering position to compensate for the mixed temperature fluctuation. The spring 47 exerts a preload in the direction toward the operation lever 3.

DESCRIPTION OF SYMBOLS 1 Thermostat mixing valve 2 Position adjustment unit 3 Operation lever 5 Thermostat cartridge housing 7 Head part 9 Valve seat for hot water 11 Penetrating guide opening 13 Linear stroke element 15 Overload unit 16 Thread engagement part 17 Pressing member 19 Valve slider 21 Valve seat 22 Recess 23 Water adjustment gap 25 Hot water adjustment gap 27 Mixed water chamber 29 Thermostat spring 31 Upper support point 33 Annular shoulder 35 Lower support point 37 Inner shoulder 39 Guide part 41 Annular gap 43 Valve seat for hot water Inner shoulder of the valve 45 Axial end face of the valve slider 47 Biasing spring

Claims (8)

A thermostat mixing valve used for a sanitary faucet that mixes water and hot water and adjusts the mixed water temperature to a target mixed water temperature that can be set on the user side by the position adjustment unit (2).
The position adjusting unit (2) cooperates with the valve slider (19) capable of adjusting the raising / lowering position in the axial direction via the linear stroke element (13), and when adjusting the raising / lowering position of the valve slider (19), The flow cross sections of the adjustment gap (23) and the hot water adjustment gap (25) are variable, whereby the mixing ratio between water and hot water can be adjusted,
A thermostat element (29) made of a shape memory alloy, the thermostat element (29) being in abutment with the linear stroke element (13) at a first support point (31), the thermostat element The structural length in the axial direction of (29) changes so that the mixed water temperature variation can be compensated when the mixed water temperature varies,
Adjustment of the lift position of the valve slider to compensate for the mixed water temperature fluctuation is performed by reducing or increasing the preload of the biasing spring (47) acting on the valve slider (19).
In thermostat mixing valve,
The valve slider (19) has a support base (37) on which the thermostat element (29) is supported by a second support point (35), A thermostat mixing valve, characterized in that the thermostat element (29) is interposed between the position adjustment unit (2) and the valve slider (19) in the axial direction of action. The valve slider (19) and the thermostat element (29) are disposed in a cartridge housing (5), and the cartridge housing (5) includes a head portion (7) and a hot water valve seat (9). The head portion (7) has a penetration guide (11) for the linear stroke element (13) and / or
The thermostat mixing device according to claim 1, wherein the biasing spring (47) is supported in an axial direction between the valve seat (9) for hot water and the end face (45) of the valve slider (19). valve.   The thermostat mixing valve according to claim 1 or 2, wherein the thermostat element (29) is a coil spring made of a shape memory alloy.   The valve slider (19) has a double valve seat (21) protruding radially outward, and the double valve seat (21) is formed in the cartridge housing (5) over an axial stroke. Within the recess, the lift position can be adjusted in the axial direction, and is spaced apart from the water adjustment gap (23) closer to the position adjustment unit (2) in the axial direction and from the position adjustment unit (2) in the axial direction. The thermostat mixing valve according to any one of claims 1 to 3, wherein a hot water adjustment gap (25) on the side is formed.   When the mixed water temperature fluctuates as the mixed water temperature rises, the structural length in the axial direction of the thermostat element (29) increases, and the flow cross section of the water adjustment gap (23) expands and at the same time the hot water adjustment gap The thermostat mixing valve according to any one of claims 1 to 4, wherein the flow cross section of (25) is reduced.   When the mixed water temperature fluctuates as the mixed water temperature decreases, the structural length in the axial direction of the thermostat element (29) is reduced, and the flow cross section of the water adjustment gap (23) is reduced. The thermostat mixing valve according to any one of claims 1 to 5, wherein the flow cross section of (25) is enlarged.   The linear stroke element (13) has an annular shoulder (33) as a support base for the first support point (31) of the thermostat element (29), in particular the annular shoulder (33) The thermostat mixing valve according to any one of claims 1 to 6, wherein the thermostat mixing valve is arranged inside the cartridge housing (5).   The linear stroke element (13) extends beyond the annular shoulder (33), in particular with a cylindrical guide part (39), the guide part (39) being a sleeve-shaped valve slider. The thermostat mixing valve according to any one of claims 1 to 7, wherein the thermostat mixing valve is arranged radially inward of (19) and forms an annular gap (41) in which the thermostat element (29) is arranged.