NO146215B - THERMOSTAT CONTROLLED FOR HOT AND COLD WATER - Google Patents

Description

The present invention relates to a thermostatically controlled mixer for hot and cold water, and of the type specified in the introduction to the subsequent claim 1.

Until now, it has been necessary to design such thermostatic mixers large and towering in order for them to be able to accommodate the necessary components. The supply of the hot and cold water to the heat sensor body has taken place via molded channels in the elongated housing. The molding and processing of such a house is relatively complicated and labor- and material-intensive.

The purpose of the present invention is to produce a thermostatically controlled mixer with a simple and compact construction and which is less bulky and cheaper to manufacture than the previously known thermostatic mixers.

This is achieved with the help of the characteristic features

which is stated in the subsequent claim 1 as well as in the subsequent independent claims.

In the following, the invention will be explained in more detail with reference to the drawing which shows some examples of execution. Fig. 1 is a section through an embodiment of the mixer according to the invention. Fig. 2 is a section through the regulating member according to the embodiment in fig. 1,

fig. 3 is a section along the line III-III in fig. 2,

fig. 4 is a section along the line IV-IV in fig. 2,

fig. 5 is a section through another embodiment

for the mixer according to the invention,

fig. 6 is a section through the regulating member according to the embodiment in fig. 5,

fig. 7 is a section along the line VII-VII in fig. 6,

fig. 8 is a section along the line VIII-VIII in fig. 6,

and

fig. 9 is a section through a further embodiment of the mixer according to the invention.

According to the embodiments in fig. 1-8, the thermo-static mixer comprises an elongated housing 10 at one end of which an inlet 11 is arranged for e.g. hot water, and at the opposite end of which there is an inlet 12 for cold water. An outlet 13 for mixed, tempered water is arranged at the middle parts of the house 10. The amount of water flowing out is determined by means of a first operating device 14, and the temperature of the water is adjusted by means of a second operating device 15.

The one medium, e.g. the hot water is supplied to the mixer through the inlet 11 and then flows through a supply pipe 16, which is arranged centrally in the housing 10 and is resiliently supported in the axial direction. The support surface of the spring 17 is formed by the end cap 18 of the housing 10. The end of the supply pipe 16 facing the inlet 11 is stored in a regulating member 19. From the supply pipe 16, the hot water flows into the regulating member 19, where it is mixed with cold water, after which the mixed water flows around a in the regulating member 19 arranged, wax-filled heat sensor body 20 before it flows out through the outlet 13.

For the sake of clarity, the inlets 11 and 12 and the outlet 13 are shown in the same direction in all the design examples, while in reality, depending on local conditions, they are most often placed on different sides of the housing 10.

According to the embodiment in fig. 1-4, the regulating member 19 consists of a sleeve displaceable in the axial direction, provided with a partition wall 21 which is provided with a number of small holes 22 distributed along the upper half of the partition wall 21's periphery. Hot water flows in through the holes 22 in the partition 21 to a first chamber 23 arranged in the regulating member 19, in which the front part of the heat sensor body 20 is occupied. The cold water flows from the inlet 12 via a second chamber 24 arranged in the regulating member 19 into the first chamber 23 through small holes 25 in an inner annular flange 26 on the regulating member 19. The holes 25 in the flange 26 are arranged directly opposite the holes 22 in the partition 21. The hot and cold water are mixed in the first chamber 23 and simultaneously circulate around the heat sensor body 20, after which the mixed water flows out through an outlet port 27 in the regulating body 19, which outlet port 27 is located diametrically in relation to the holes

22 and then flows on towards the outlet 13.

Directly opposite the outlet 13, a sleeve-shaped body 28 is arranged inside the housing 10, oriented in the longitudinal direction of the housing 10 and which surrounds the supply pipe 16. The sleeve-shaped body 28 is designed so that its outer edges are in tight contact with the inner wall of the housing 10, while a circumferential channel 29 , which is in connection with the outlet 13, is formed outside the middle part of the sleeve-shaped body 28. The channel 29 is connected via a gate 30 to a circular passage 31 which is formed between the supply pipe 16 and the sleeve-shaped body 28. The water flows into the passage 31 and via the gate 30 to the channel 29 and out through the outlet 13. The gate 30 can be closed of a valve body 32 which is displaced to and from the port 30 by means of the first operating handle 14, which thus determines the amount of flowing water.

The regulating member 19 is, by means of the second operating member 15, over a spindle 33, the free end of which is threaded into a sleeve 34, axially displaceable in the housing 10 and is under the influence of a spring 35, whose support surface is formed by the sleeve-shaped body 28 against the regulating member 19 facing end.

The rear end of the heat sensor body 20 abuts against a transverse partition 36 in the sleeve 34, and a circumferential flange at the middle part of the sensor body 20 abuts with its front end against the ring-shaped flange 26 in the regulating member 19. By displacing the regulating member 19 upwards in the figure, the distance between the outlet of the supply pipe 16 and the partition 21 in the regulating body 19, whereby the supply of hot water decreases. At the same time, an increase in the cold water supply is achieved through an increase in the distance between the end of the regulating body 19 facing the cold water inlet 12 and a tubular nipple 37 screwed into the housing 10, in which nipple the sleeve 34 is displaceably mounted and the spindle 33 is rotatably mounted. An increase in the temperature of the mixed water is achieved in a similar way by a displacement of the regulating member 19 downwards in the figure.

In the event of an increase in the temperature of the mixed water beyond the set, a longitudinal expansion of the sensor body 20 takes place, whereby the regulating member 19 is displaced upwards in the figure and produces a lowering of the water's temperature to the set temperature. Correspondingly, a decrease in the temperature of the mixed water results in a decrease in the length of the sensor body 20, whereby the regulating member 19 under the influence of the spring 35 is displaced downwards in the figure and produces an increase in the temperature of the water.

In the design example according to fig. 5-8, the regulating body 19 is designed in a slightly different way. The cold water supply here takes place from the inlet 12 and via a number of axial channels 38 arranged in the regulating body 19 into the space between the partition wall 21 and the outlet of the supply pipe 16. There is a mixture with the hot water, after which the mixed water flows over a number of holes 39 in the partition 21 into the first chamber 23 of the regulating body 19, where it flows around the sensor body 20 and then via a number of radial openings 40 in the regulating body 19 flows towards the outlet 13. I contrast to in the design example in fig. 1-4, there is a mixing of the hot and cold water outside the first chamber 23.

In the design example according to fig. 9, the outlet 13 and the inlet 12 have switched places, so that the liquid flowing in from the inlet 12 passes on the outside of the regulating member 19 and in front of the partition wall 21, where it mixes with the liquid from the supply pipe 16. In this embodiment, the partition wall 21 forms one end closure of the regulating member 19 , and the tubular nipple 37 extends closest to the partition wall 21, so that only a narrow channel is formed between the partition wall 21 and the front end of the nipple 37. The width of the gap is changed by the axial displacement of the regulating member 19, whereby the amount of inflowing liquid from the inlet 12 is regulated, while at the same time a change is achieved in the distance between the partition wall 21 and the outlet of the supply pipe 16, for regulation of the amount of inflowing liquid from the inlet 11.

The axial recess in the nipple 37 is wider at its front part facing the regulating member 19, and in this extended part of the recess the heat sensor body 20 is accommodated, the front end of which rests against the partition wall 21 in the regulating member 19. In the event of a change in the length of the heat sensor body 20 an axial displacement of the regulating member 19 is achieved, in the same way as previously described.

The mixed water flows towards the outlet 13 via a port 41 in the nipple 37, which port can be closed using the valve body 32.

Claims (5)

1. Thermostatically controlled mixer for hot and cold water of the kind that consists of an elongated housing (10) which is provided with an outlet (13) for mixed water and each its own . inlet (11,12) for hot or cold water, and where a first operating means (14) is arranged for quantity regulation of flowing liquid and a second operating means (15) is arranged for temperature regulation of the liquid by means of a heat sensor body (20) placed in a regulating means (19) on such way that a change in the axial extent of the heat sensor body (20) results in an axial displacement of the regulating body (19) in the housing (10) to achieve a changed ratio between the inflow areas of the liquids, as supply passages for the liquids are arranged from the respective inlets to the heat sensor body , and where the one liquid supply passage comprises a supply pipe (16) centrally located in the housing (10), characterized in that the regulating member (19) consists of a sleeve-shaped member axially displaceable and spring-loaded in the housing (10), and provided with a wall (21) between and directly outside the outlet of the supply pipe (16) and the heat sensor body (20), that the regulating member (19) is displaceable and sealingly stored around the supply the outlet end of the seal pipe (16), that the regulating body (19) and its wall (21) are displaceable to and from the outlet of the supply pipe (16) and that a number of holes (22) are arranged in the wall (21) next to the outlet of the supply pipe, for the first liquid, the first liquid being mixed with the second liquid at the front of and/or around the heat sensor body (20). 2. Mixer according to claim 1, characterized in that the regulating member (19) is provided with an inner, ring-shaped flange (26) in whose central opening the front part of the heat sensor body (20) is placed, and that there in the regulating member (19) between the wall (21), the flange (26) and the front part of the heat sensor body (20) form a chamber (23), in which at least one outlet port (27,40) is arranged. 3- Mixer according to claim 2, characterized in that the second liquid, before mixing with a first liquid, is arranged to be supplied to the chamber (23) via holes (25) in the annular flange (26), which holes are arranged directly opposite the holes (22) in the wall (21), and that the outflow of liquid from the chamber (23) takes place through said outlet port (27) which is diametrically opposite the holes (22) in the partition. 4. Mixer according to claim 2, characterized in that the regulating member (19) is designed with a number of axial channels (38), through which the second liquid is arranged to flow from the inlet (12) to the space between the wall (21) and the supply pipe's ( 16) outlet, in which room a mixture with the first liquid takes place, and that the mixed liquid is arranged to flow into the chamber (23) via hole (39) in the wall (21). 5. Mixer according to claim 1, characterized in that the wall (21) forms one end of the regulating body (19), that the front end surface of the heat sensor body (20) is arranged to rest against said wall, and that the other liquid is arranged to flow from the inlet (12) past the regulating member (19) on its outside and in front of the wall (21) for mixing with the first liquid.