SE460223B - TRIPLE STEERING HEAT EXCHANGER WITH THIS CONNECTED FRAMEWORK VOLUME FOR THE HOT WATER CONNECTED TO THE SPRING HEATER - Google Patents

Description

460. 225 10 15 20 25 30 35 steps to transfer heat energy to the radiator water and the consumption hot water or possibly to other fluids.

The district heating water flow can be controlled relatively easily of a valve, preferably a so-called thermostat valve existing of a valve unit and a control unit or thermostat. Usually the valve unit is placed on the inlet side of the district heating water and the thermostat on the return side. A control line connects the with the thermostat so that the valve opens and closes desired temperatures on the return water. The regulatory guidance can be made of a liquid-filled capillary with a capillary fluid, the volume of which changes with temperature and thereby provides more opening and closing of the valve. One such control unit is relatively small and prlsblllíg.

When using storage heat exchangers, it is normally transferred the district heating water's heat energy to radiator water and part of this energy was then used to heat the storage water in the boiler. This is normally dimensioned for at least it water amount. which is used for a normal bath, and may have a significant volume. However, a disadvantage of storage heat exchangers is that it after a large hot water outlet takes a relatively long time to protect the next volume of water in the boiler to the correct temperature.

Furthermore, a storage heat exchanger is large and relatively heavy, for it takes several men to transport it into it building in which it is to be installed.

However, with storage heat exchangers, one has a not insignificant one heating buffer for both the radiator water and the consumption heating the water. As a result, the heat exchanger itself does not have to for the maximum load, which is particularly more in the case of large domestic hot water drains, which here that the culvert side can be made smaller, which in turn culvert and other construction costs 1 district heating central favorable. P.g.a. its dimensions can be stored switches in practice are not used at high power requirements. i.e. l house with many apartments, and normally one should not be able to use the 1 house with more than 6 - 10 apartments. 10 15 20 25 30 35 460 223 The object of the invention is to provide a device of mentally mentioned kind. which combines the benefits of using the use of direct heat exchangers and storage heat exchangers without suffer from the disadvantages of such use in the past added by.

This is achieved according to the invention with a device according to with that specified in claim 1. By the storage function is only active in the case of larger hot water outlets, in normal operating conditions to work with direct heat generation ling. The weight of the boiler is compared with previous storage exchanger more than halved and the size of the device becomes despite the processor not larger than a conventional device with direct changer due to that the peripherals of the device compared with a conventional direct exchange device is relatively small bulky. Furthermore, the units can be built up to effects around and over 100 kw without becoming heavy and bulky and the little ones can easily be carried into a two-person property. An- the closures can easily be made for both top and bottom mounting.

The invention will be described in more detail below with reference to showing to the accompanying drawing, which schematically shows a embodiment of a device according to the invention.

The device shown in Fig. 1 comprises a three-tube heater. exchanger 2 consisting of three coaxial thin tubes, 2.1, 2.2, 2.3, which are preferably made of copper. Thereby an inner channel 40 is formed, an intermediate ring channel 18 and an outer ring channel 17 (see the detail view on a larger scale of one cross section through the heat exchanger). The outer ring channel 17 of the heat exchanger 2 is connected to the district heating network and as indicated by arrows in the figure the water flows from the district heating network through the line 4 and via a dirt filter 21 through the valve 19 and into the channel 17 in the heat exchanger i figure right end. After flowing through the channel 17 and where it has given off some of its heat, district heating water flows through the heat exchanger in the left end of the figure and into return line 3. The flow in channel 17 is regulated by '460 223 10 15 20 25 30 35 the valve 19 through a thermostat 20 in the return line 3, which are connected to the control valve through the capillary tube 37. the duct 18 in the heat exchanger 2 is connected to the radiator circuit l in the residential property to be heated. In the schema- fl_ only one radiator has been drawn. In doing so, return water from the radiators through line 6 and in the channel 18 J of the heat exchanger in the left end of the figure and the current mar 1 opposite direction to the district heating water through it channel and out through line 5. A circulation pump 23 with shut-off valves regulate the circulation at the stop the radiator circuit. Furthermore, this circuit comprises a so-called village- -pass line 24. which via a shunt valve 22 leads inward radiator water to the return line 6 to 1 month of need mix the outgoing radiator water to the correct temperature.

The shunt 22 can optionally be motor controlled by thermostats, a outdoor and an indoor thermostat.

Cold water enters from a line 8 in the figure on the left the part of the heat exchanger 2 in 1 the duct 40. From the duct 40 opposite end, a line 16 leads down into a hot water shipowner 10. A line 7 leads from the upper end of the shipowner 10 to 1 residential property occurring hot water outlet.

The hot water line 7 is through a mixing valve 26 via a branch line connected to the cold water line 8 to mix the hot water with cold water if one of the the valve pre-set hot water temperature is exceeded.

The device also includes a heat holding circuit for keep the water in the boiler l0 warm during periods without water drains. This circuit includes a circulation pump ll which from a line 13 opening into the upper part of the boiler 10 pumps hot water through a line 14, as via a non-return valve 15 is connected to the inlet end of the channel 40. During silent stand perlodes thus flow hot water from the boiler 10 sf * through line 14 and into channel 40 l heat exchanger, i which it is heated. and then returned through line 16 to the bottom part of the boiler. 10 15 20 460 223 s There is a filling valve for filling radiator water 28, which can fill the system via the tube 33. Further includes an expansion system 27, which is to hold the system the pressure. i.e. radiator pressure, at a preset value of about 1.5 atö. This system includes a manometer 29, a aerator 30, a safety valve 31 and an expansion vessel 32.

The expansion vessel is of the closed type with a rubber membrane which separates the radiator water from an air-filled chamber.

The heat exchanger 2 schematically shown in the figure is a semicircular formig. In practice, a heat exchanger that encloses is preferred the boiler 10. Furthermore, the heat exchanger may consist of one or several parallel-connected three-pipe loops with parallel-connected channels, as indicated in the left part of the figure by reference The designation 12. At least the heat exchanger 2 and the the shipowner 10 is built into a cabinet 34 and insulated with urethane 35.

In describing the device according to the figure, the heating water connected to the duct 17. Of course can the district heating water is instead connected to the ring duct 18 and it is also conceivable to connect the district heating water to it inner channel 40 without departing from the invention. Preferred however, the cold water enters the inner channel 40.

Claims (7)

460 223 Patent claims Device for supplying smaller residential properties and the like connected to a remote protection network with hot water for heating and consumption. which device comprises a heat exchanger (2), a radiator circuit (1). warning water outlet (7). a cold water inlet (8) is a warning water heater (10), characterized in that the heat exchanger consists of at least one three-pipe heat exchanger (2). which tube (2. l 2.2. 2.3) delimits an inner tube channel (40) and two coaxial annular channels (17, 18) with the inner channel. of which channels a first channel is connected to the radiator circuit (1) so that a closed circuit is formed, a second channel is connected to the remote protection network and a third channel, the inlet of which is connected to the cold water inlet (8). is connected via the boiler (10) to the hot water outlet (7) and by the device comprising. a warning circuit (13, 11, 14. 6. 40. 16), which during periods without hot water draining from the boiler (10) forms a closed circuit. in which the water in the boiler is circulated by means of a pump (II) through the channel (40) connected to the boiler in the heat exchanger (2) and back to the boiler. Device according to Claim 1, characterized in that a non-return valve (15) is included in the heating circuit. which non-return valve prevents cold water from flowing into the hot pouring circuit during hot water draining from the boiler. Device according to any one of claims 1-2. characterized in that the device comprises several three-tube heat exchangers (2). whose channels are connected in parallel. Device according to one of Claims 1 to 3. KNOWN that the heat exchanger or heat exchangers (2) are designed to enclose the boiler (10) around its largest diameter. Device according to any one of claims 1-4. FEATURES that the district heating water flows in the heat exchanger (2) or the heat exchangers in the opposite direction to the water in the radiator and boiler circuits. Device according to one of the preceding claims. feel that the cold water flows through the inner pipe channel (40) and the radiator water in the outer ring channel (17). Device according to any one of claims 1-5. FEATURES that the district heating water in the heat exchanger (2) or the heat exchangers passes through the outer ring duct (17).