SE439354B - FLUID MIXER DEVICE - Google Patents

Description

«Ysousszz-o .of a tenmostat, which is mechanically coupled or arranged to actuate the valve means. The conventionally used thermostat comprises a body which is arranged in a mixing chamber or the fluid line D of the mixed water downstream of the equalization valve, which thermostat reacts to temperature changes of the mixed water.

This known device has several disadvantages in certain applications and installations. In particular, the time delay of the thermostat in the event of temperature changes is often large and it cannot be adapted to rapid temperature variations in the mixing chamber. In several known fluid mixers this disadvantage is exacerbated, since a complete mixing of the hot and the cold water has not taken place, where the thermostat is located. In addition, in the known types of thermostats with mechanical actuation of the valve, heat transfer from a D surface in contact with the water to a thermally sensitive material, e.g. wax, whereby the heat transfer rate becomes low and / or non-uniform. In addition, with certain thermally sensitive materials, the optimal function of the thermostat is limited to a narrow temperature range. In case of large fluctuations in the temperatures in the hot and / or the cold water supply to the mixer, e.g. in circulating installations, or where there is a requirement for a high inflow velocity, the tenmostat does not work satisfactorily with mechanical actuation of the valve. The installation can in some cases D be modified by using special valves in the circuit, but this is inappropriate and very costly.

An object of the present invention is to provide a fluid mixer which obviates the above-mentioned disadvantages and in addition is designed so that it entails several improvements and advantages of a special technical nature, which will be described in the following.

The present invention relates to an apparatus for a fluid mixer of the kind comprising a body having a body of a type. hot water inlet and a cold water inlet, a setting valve for controlling the relative proportions with which hot and cold water are mixed, means for setting the desired temperature of the mixed water, a motor which is operably connected to the the position valve for influencing it, and a temperature probe, which is arranged to sense the temperature of the mixed water and is connected to an electronic control device for the motor for controlling the mixing valve corresponding to the temperature of the mixed water, which temperature is sensed by the temperature probe, which is characterized in that the setting valve consists of a shuttle valve, which consists of a hollow cylinder with opposite end sealing surfaces, and the shuttle valve is mounted in the body and sealed. in relation thereto in order to separate the hot and cold water inlets by means of sealing means arranged to cooperate with the body and to be brought into engagement with the inside of the cylinder between the end sealing surfaces, that the shuttle valve is axially displaceable in the interior of the body to displace the sealing surfaces in opposite seats, which belong to the hot and cold water inlets for the purpose of adjusting the proportions of hot and cold water, which are discharged to a mixing pipe, which is curved to effect mixing of the water flowing therethrough and that the temperature probe is mounted in the body and extends into the mixing line downstream of a part of the curved part of the mixing line bent in the other direction. Other features of the invention appear from the subclaims.

Further features of the invention appear from the following description of an embodiment, shown in the accompanying drawings, in which Fig. 1 shows a block diagram illustrating the principal mode of action of the fluid mixer, Fig. 2 shows a section from the side of the fluid mixer, which section illustrates the body, the cover and the equalizing valve means, Fig. 3 is an end view of the device according to Fig. 2, in the direction of the arrow III in Fig. 2 but with the end plate of the cover removed, and Fig. 4 shows partial cross-section along the line IV-IV in Fig. 3.

The diagram in Fig. 1 shows how hot and cold water supply lines 1 resp. 2 opens into a setting valve 3. A line 4 for mixed water leads from the setting valve 3 and can in a known manner be connected to a plumbing system or other water supply line and distribution system. Mounted in the line 4 is a temperature sensor or probe 5, which is suitably constituted by a resistor with a negative temperature coefficient, for example, a thermistor, which is connected in parallel with another resistor and other components, which are selected so that the net resistance of the temperature probe will vary linearly relative to temperature changes, and to calibrate the thermistor so that it emits an output signal for the correct or actual temperature.

The desired temperature of the mixed water is set in advance by means of an input potentiometer 6, which is connected to a voltage comparator circuit 7, which is suitably constituted by a printed circuit board, which may comprise the components or circuits desired to fulfill associated functions depending on the system or in-i. the stallation, e.g. time management, recording of data or other requirements. In 8005532-0 the comparator circuit 7 emits a signal, which is applied to a motor and gearbox 8, through a power amplifier 9.

The drive motor is connected to the setting valve 3, so that when sensing and reacting to a temperature change in the line 4 relative to the preset, desired, motor, the setting valve 3 acts so that it varies the flow of hot or cold water from the inlet supply lines 1, 2. , so that the desired, preset temperature is maintained.

The device for accomplishing this will be described in more detail with reference to the other drawing figures.

The device comprises a body 10, which has an inlet chamber 11 for hot water and another inlet chamber 12 for cold water. Appropriate screw threads, pipe connections or gaskets should be used for connection to the water supply lines. A cover 13 is mounted on the body 10 and the motor is supported in the interior of the cover 13. The motor consists of a reversible DC motor with a gearbox and is designated as a unit with 14. The motor and the gearbox are suitably connected by means of a clutch or the like, so that the gearbox output gears can not be damaged in case the motor is exceeded, failing or subjected to an overload. situation. The various electrical connections and electronic parts, which comprise a printed circuit board 15, are also enclosed by the housing 13, which forms an enclosure for these, the body 10 and the housing 13 are held together by bolts and are insulated from each other by a suitable gasket 16 and in addition spacers 47 are arranged between the bolts and the cover 13. The body and the cover may consist of different materials, and the cover 13 may constitute a heat dissipation for the heat generated by the electrical or electronic parts which are enclosed therein. The placement of the cover in relation to the body and the attachment of the cover to the body can provide a waterproof enclosure for the electrical components.

A liner 17 is mounted in the interior of the body 10 and sealed thereto by means of O-rings 18.

The spacer 17 is held in place by a support member 19 which extends into the housing of the housing. The support element 19 forms an end part or a lid which closes the body TO relative to the housing 13, and the support element 19 comprises a bracket 20 for the engine and the gearbox 14 and has a shoulder hole, in which year a bushing 21 is provided, through which a push rod 22 extends. in the body, 10. The push rod 22 is connected to the support member 19 by means of a flange seal 23 to prevent water from penetrating from the body 10 into the housing, and there is a further seal 48 on the other side of the bushing 21.

As a safety measure, a valve 49 leads from the space between these two seals to the surroundings, and in a known manner the support is tightly connected to the body 10. In this way it arises through the valve 49, if either of the two seals 23, 48 should yield. a visible indication of a water leak on the outside of the device, before the water penetrates into the housing 13, where the electronic parts are located. The push rod 22 is for reciprocating motion, coupled to the engine and gearbox 14 by means of a shaft 24, which comprises a universal joint for transmitting the rotational motion to the reciprocating motion, while allowing the shaft to be misaligned. . A cylindrical shuttle valve 25 is mounted in the body coaxially with the liner 17 and comprises a substantially hollow, cylindrical element 26, which is provided with a central inner cross or arm 22, which is provided with a perforated hub 28. The valve element 26 hollow interior forms a fluid inflow path for hot water from the chamber 11. The free end of the pressure rod 22 is connected to the hub 28 by means of a threaded bracket 29 which engages the threaded end of the pressure rod, and a bent sleeve 30 on the pressure rod forms a consideration against which abut a resilient part, e.g. and O-ring.

There is a free opening in the hub 28, and a further resilient part 32 engages in the opposite side of the hub and is held by a washer and the screw connection 29 on the threaded end of the push rod at a predetermined load, which is regulated by the sleeve 30. On thus, the resilient attachment of the shuttle valve 25 to the push rod 22 allows a limited movement for self-centering or correct alignment during operation.

The valve element 26 has two opposite, annular sealing surfaces 33, 34, which are arranged to engage with each of two opposite seats 35, 36, which are mounted in the body 10. The diameter of the shuttle valve element 26 is approximately the same as for the annular seat surfaces, so that incoming hydraulic pressure acting on the shuttle valve is substantially balanced, thereby avoiding all tendencies of the hydraulic pressure to upset the shuttle valve. In addition, the diameter of the push rod is small, so that the effect of the hydraulic pressure thereon is negligible. The seat 36, which extends into the hot water inlet chamber 11, is provided with a metal ring which is attached to an inner hub 37 in the body. The second seat 35, which is connected to the cold water inlet chamber 12, is provided with a metal ring, which is located between the liner 17 and the support element 19. The metal rings are suitably _. . .-..._......__..____._.___ í_ -__.-__-.___-__._ ..... ___.,, _., _____..- ~ __ The sockets made of hard, stainless steel and the opposite seat surfaces 33, 34 of the valve element are constituted by narrow annular collars, formed by the corresponding edge end portions of the valve element being tapered. This device means that high intermediate surface pressures can be achieved during operation between the seat in question and the adjoining surfaces of the valve elements, so that all accumulations of slag or other contaminants are destroyed or removed and can not interfere with the proper operation of the shuttle valve. The use of hard, stainless steel is also suitable for achieving wear and corrosion resistance in the device. The inlet chambers 11, 12 of the body are separated by the inner partitions of the body, the partition wall 17 and the shuttle valve 25. The spacer is formed with an inwardly directed flange 38, which has an annular groove, which correctly adjusts an O-ring seal 39, which seals against the valve the outer surface of the ment 26. At low pressure, the seal 39 rests radially inwards against the valve element 26 to ensure that it maintains a light pressure connection therewith. The seal 39 allows even low-friction movement of the valve element 26 during operation and distinguishes the hot and cold water inlet chambers 11, 12. The low frictional resistance ensures that the force consumption for a reciprocating movement is small.

It can be seen from the above description of the shuttle valve 25 and the associated seats 35, 36 that the seat 35, which is connected to the hot water inlet chamber 11 and the sealing surface 34, has an opening through which hot water from the hot water inlet chamber can flow when there is an opening between this sealing surface and the seat. The hot water chamber 11 is of course insulated from the cold water chamber 12, when the valve sealing surface 34 engages with the seal 36. For the cold water chamber 12 there is a similar arrangement with respect to the seat 35 and the sealing surface 33.

By cooperation between the shuttle valve and the opposite, opposite seats, openings are formed, through which hot and / or cold water can flow at speeds determined by the position of the shuttle valve. The hot water flow from the chamber 11 is led through the inner passage by means of the shuttle valve element 26 and further towards the second, opposite seat 35, through which cold water can flow from the cold water chamber 12.

The support element 19 has a hole 40, which leads to a mixing line 41, into which the hot and / or cold water flows from the shuttle valve. The mixing line is partly formed by the body, the intermediate position and the support part and is designed above all to ensure correct mixing of the hot and / or cold water. The conduit has a transverse portion leading from the hole 40, which tends to mix the water in a swirling and / or turbulent manner as it flows through the conduit 41 to an oppositely curved portion 42, which leads from an outlet 43 on body 10, which outlet is connected in a known manner to the pipe installations, systems or the like by means of suitable, gaskets, couplings or similar connections. The mixer tube 41 is substantially helical to effect agitation of the mixture and to avoid pocket formation in hot and / or cold water when the mixture reaches a temperature probe 44 mounted in the body 10 and extending into the downstream conduit. about the helical fluid line.

The temperature probe 44 extends into the center of the stream of mixed water and comprises, as mentioned above, a thermistor with an associated calibration and linear control circuit, which is connected to the * 1 Fil 0012 Qïmmfffa in the electronic control device with the printed the circuit board 15, which is mounted in the housing 13; The temperature probe 44 is also connected to a visual, digital indicator panel 45, which is located on the end panel 46 of the housing, so that the actual g temperature of the mixture becomes directly readable. The electronic control device further comprises a variable potentiometer (not shown), which can be preset by means of a screwdriver or by means of a setting knob with hands digits in a known manner for indicating the temperature setting.

Alternatively, the electronic circuit may be adapted to give a visual indication of the preset temperature by means of a suitable switch or pre-d channel which can be activated when the variable potentiometer is corrected or in need of checking. D - The capacity and performance of the various electronic and / or electrical components must be chosen so that they are greatly oversized for normal operation and thus exhibit maximum values for service life and safety. 7 In addition, the mixer is arranged so that it can be connected to hot and cold water measuring lines in opposite positions, ie. the hot and cold water inlet chambers described above are reversed. A simple switching plug for the electrical connection to the engine and gearbox through the electrical control can be used and this reverses or mirrors the smoothing direction of movement of the shuttle valve. D D When operating a mixer according to the invention, it has been found that correct temperature control can be achieved of the order of É 100 or less.

In addition, it has been found that the fluid mixer can operate within very large ranges of flow rates, e.g. within the range 300 - 10 l / min. These flow rates can be considered as approximate values of the maximum flow rate that may be required in a pump-driven bypass system to the minimum value of a circuit at idle. The advantages of visual indication of the actual temperature and other properties mentioned above will be appreciated by one skilled in the art. In addition, the manufacture and construction of the fluid mixer is such as to obtain high reliability, easy manufacturing procedure, easy assembly, easy maintenance, if required, and easy installation for maintenance.

Late.

POOR QUALmr

Claims (5)

8005532-0 om P a t e n t k r a v A device for fluid mixers of the kind comprising a body (10) having an inlet (11) for hot water and an inlet (12) for cold water, a setting valve (3) for controlling the relative proportions, with which hot and cold water is mixed, means for adjusting the desired temperature of the mixed water, a motor (14) operably connected to the setting valve (3) for actuating it, and a temperature probe (44) arranged to sense the temperature of the mixed water and is connected to an electronic control device for the motor (14) for controlling the mixing valve (3) corresponding to the temperature of the mixed water, which temperature is sensed by the temperature probe (44), characterized in that the setting valve (3 ) consists of a shuttle valve (25), which consists of a hollow cylinder (26) with opposite end sealing surfaces (33, 34), and the shuttle valve (26) is mounted in the body (10) and sealed in relation to it for separating the inlets (11, 12) for hot and cold water by means of sealing means (39), which are arranged to cooperate with the body (10) and to be brought into engagement with the inside of the cylinder (26) between the end sealing surfaces (33, 34 ), that the firing event (25) is axially displaced in the interior of the body (10) to displace the sealing surfaces (33, 34) relative to opposite seats (35, 36), which belong to the inlets (11, 12) for hot and cold water for the purpose of adjusting the proportions of hot water and cold water, which are discharged to a mixing line (41), which is curved to effect mixing of the water thereby flowed through and the temperature probe (44) is mounted in the body (10) and extends into the mixing line (41) downstream of a bent (42) part of the curved part of the mixing line (41) in the other direction. Device according to claim 1, characterized in that the end-sealing surfaces (33, 34) comprise narrow annular, beveled surfaces formed by tapered edge end portions on the valve element (26), and that the seats (35, 36 ) consists of hard material, preferably metal, e.g. stainless steel. Device according to claim 1 or 2, characterized in that the shuttle valve (25) is elastically mounted on a pressure rod (22) which is operatively connected to the motor (14) and arranged to displace the shuttle valve (25) back and forth. between the seats (35, 36). Device according to one of the preceding claims, characterized in that the sealing means (39) consist of a single O-ring seal (39), which is supported by a liner (17), which is mounted in the interior of the valve body (10). ), and the seal (39) is slightly tensioned radially inwards to provide a light pressure engagement with the outside of the element (26). Device according to any one of the preceding claims, characterized in that the temperature probe (44) comprises a thermistor with an associated calibrating linear control circuit, which is connected to the electronic control device for effecting a linear reaction over a selected operating temperature and that the probe (44) is arranged to extend into the center stream of the mixed water stream. li-'Üooa QUALITY