DE9311855U1 - Temperature control unit and water supply system - Google Patents

Description

HAIGES ft 200.629

Temperature control device and

Water supply system

Description

The invention relates to a temperature control device for liquids, in particular drinking water, with a heat-storing container, which is provided with two connections for a liquid supply line or discharge line; as well as a water supply system with at least one water extraction point and a flow and return line between this point and a remote connection of these lines. Heating devices in the form of boilers and instantaneous water heaters are known on the one hand, and water supply systems with an open water circuit that is maintained by a constantly running circulation pump on the other. The flow of the circulating water, which can be extracted at one point or another, usually prevents the water from freezing in the pipes in the event of frost, but not with sufficient reliability.

With the known heating devices, either a relatively large amount of water must be heated and permanently kept at a higher temperature, which also leads to limescale deposits and a relatively high energy consumption, or it must be accepted that hot water is only available after some cold water has passed through.

The invention is therefore based on the object of creating a temperature control device for liquids, in particular drinking water, which does not have to tolerate deposits in calcareous water, is economical in terms of energy consumption and yet can immediately dispense tempered liquid at any time; as well as designing a water supply system with improved frost protection.

This object is achieved according to the invention in a temperature control device of the type mentioned at the outset in that its two connections are connected to one another by means of a liquid-carrying heat exchanger which is embedded in a heat-storing mass (for example water or oil) arranged in the container; and in a water supply system in that the connection of the supply and return lines remote from the water extraction point is formed by the heat exchanger of a temperature control device according to the invention.

The invention therefore proposes heating the liquid to be used (for example drinking water for animals) to be taken from the temperature control device using a medium with a relatively low temperature (approx. 30 °C to 40 °C) to approximately the same temperature when the liquid is standing in the heat exchanger and to a correspondingly lower temperature when the liquid is slowly flowing through the heat exchanger, which, however, in conjunction with the movement of the liquid, is still sufficient to prevent the liquid lines from freezing outside the device up to the water extraction point.

Furthermore, the invention advantageously ensures that limescale deposits in the container of the temperature control device are largely avoided and the energy required for temperature control is reduced, while the device can always be supplied with more or less heated liquid that was supplied at a cooler temperature.

The following applies to preferred embodiments of the temperature control device according to the invention and the water supply system according to the invention:

A quantity of liquid, in particular water, is stored in the container as a heat-storing mass and can be tempered by means of a regulated immersion heater, for example by means of a thermostat-controlled radiator.

If the device’s tank has a connection with an automatic inlet valve for a water supply line for filling the tank and, if necessary, an overflow,

the container connection for the liquid supply line is connected to the mass supply line. Both the liquid to be tempered and the heat-storing liquid are therefore water from the municipal network.

The device's container is connected to the water drain or supply line via an adjustable drain valve, so that it can be easily emptied if necessary.

In a water supply system, the water supply line of which is optionally equipped with a non-return valve, the water supply line flows into the return line and, in the case of a non-return valve, the water supply line is forked between this and the inlet, so that only a single water supply line and a single non-return valve are required.

The supply and/or return line of the water supply system is equipped with a standard circulation pump, which either runs continuously or is switched on when required, if necessary together with the immersion heater of the temperature control device.

Additional embodiments and further developments of the temperature control device according to the invention are characterized in claims 8 to 10. This results in particular in that instead of a standing liquid, a temperature control liquid running through the container or instead of an electric immersion heater, an additional heat exchanger can be used to heat the temperature control liquid, whereby this heat exchanger can be located in a hot water pipe.

In the following, the invention is explained in detail using the water supply system with temperature control device shown as an example in the drawing and using two alternatives thereof.
The first figure of the drawing shows the embodiment in a schematic representation, the second also shows both alternatives

Fig. 1:
The water supply system according to the invention has on the one hand

a temperature control device 10 and, on the other hand, at a considerable distance from it, at least one water extraction point 12 with a drinking bowl 14 each, which is connected to the device 10 by both a water supply line 16 and a water return line 18, which has two connections 20 for this purpose, which are connected to one another inside its container 22 by means of an approximately U-shaped pipe 24 as a heat exchanger. This heat exchanger is embedded in a quantity of water 26 that almost fills the container 22 as a heat-storing mass, which is limited on the one hand by a float valve 28 arranged on the container 22 and on the other hand by an overflow 30 of the container. The inlet valve 28 is connected to a water supply line 32, at a point in front of which there is a check valve 34 in the line 32 and behind which this line flows into the return line 18 in front of the tank connection 20, which is provided with a circulation pump 36. This is electrically connected, as is a heater 38 arranged as an immersion heater in and on the tank 22 and a similarly arranged thermostat 40, to an electrical control device 42 which is connected to the electrical network and, when switched on, supplies both the pump 36 and the heater 38 with electrical current.

The interior of the container 22 is connected to the supply line 16 via an adjustable drain valve 44 near the container connection 20, so that the amount of water 26 can be partially or completely, slowly or quickly drained from the container, which automatically refills itself with tap water via the inlet valve 28.

The operation of the previously described example is as follows:

If the pump 36 and the heating element 38 are switched off (switching state 0), then the drinking water in the heat exchanger (U-tube 24) takes on the possibly gradually decreasing temperature of the water quantity 26 in the thermally insulated container. After switching on the pump 36 and the heating element 38, whose outputs are coordinated with one another and with the circulating or standing water quantity, more or less warm drinking water from the heat exchanger (24) initially enters the flow line 16, while later drinking water heated by the heated water quantity 26 leaves the heat exchanger. After switching on, initially unused cold drinking water from the return line 18 will also enter the heat exchanger (24), while this water can later transport residual heat that has not been released into the drinking bowls or the pipes in an almost complete water cycle. It is precisely the heat content of the circulating drinking water that ensures that pipes 16 and 18 remain free from ice.

Fig. 2:

The two alternative temperature control devices 110, whose cast-iron containers 122 each consist of two mirror-image halves 122.1 and 122.2 with a flange connection of both halves after one of them has been rotated by 180, have the two connections 120 at the same height, which are connected to one another by means of a horizontal pipe section 146 as a heat exchanger. The heat-storing water quantity 126 contained in the container 122, which completely fills it, is introduced through a filler neck 148, which allows the displaced air to escape. At diametrical points, which are as far apart as possible, the container 122 has one of two other connections 150, which can be connected to a break in a hot water (e.g. heating) line, so that the tempering water quantity 126 can be exchanged as desired, e.g. continuously.

In the first alternative, the tempering
Water flows through the cavity of the container 122 from one connection 150 to the other; in the second, however, it is stationary, while another tubular heat exchanger
152 connects the other two connections 150 and is embedded in the water volume 126 from which the
hot water that is passed through.

Claims (10)

HAIGES . &idigr; «200.629 - 7 ~ Claims 1.) Temperature control device for liquids, in particular drinking water, with a heat-storing container (22) which is provided with two connections (20) for a liquid supply line (18) or discharge line (16), characterized in that the two connections (20) are connected to one another by means of a liquid-conducting heat exchanger (24) which is embedded in a heat-storing mass (26) arranged in the container (22). 2.) Temperature control device according to claim 1, characterized in that a quantity of liquid, in particular water, (26) is stored as a mass in the container (22), which can be tempered by means of a controlled dew heater (38). 3.) Temperature control device according to claim 2, the container of which has a connection with an automatic inlet valve (28) for a water supply line (32) for filling the container (22) and optionally an overflow (30), characterized in that the container (22) connection (20) for the liquid supply line (18) is connected to the water supply line (32). 0 4.)Temperature control device according to claim 3, characterized in that the container (22) is connected to the water drain (16) or supply line via an adjustable drain valve (44). 5.) Water supply system with at least one water extraction point (12) and a supply and a return line (16 and 18 respectively) between this point and a remote connection (24) of these lines, characterized in that this connection is formed by the heat exchanger (24) of a temperature control device (10) according to claim 1. 6.) Water supply system according to claim 5 with 3, the water supply line (32) of which is optionally provided with a non-return valve (34), characterized in that the water supply line (32) opens into the return line (18) and, in the case of a non-return valve (34), is forked between this and the inlet. 7.) Water supply system according to claim 5 or 6, whose supply and/or return line (16 or 18) is provided with a circulation pump (36). 8.) Temperature control device according to claim 1, characterized in that water as a heat-storing mass (126) can be fed into or out of the container (122) through two other connections (150), whereby these two connections (150) can be connected to an interruption in a hot water line (-). 9.) Temperature control device according to claim 1, characterized in that the heat-storing mass, in particular a liquid such as water, can be temperature-controlled by means of another heat exchanger (152) which is connected to two other connections (150) of the container (122) and arranged therein, whereby these two connections (150) can be connected to an interruption in a hot water line (-). 10.) Temperature control device according to claim 2, 8 or 9, characterized in that the heat exchanger is a substantially straight pipe section (146) which connects the heat exchanger connections (120) of the container (122).