SE0802122A1 - District heating plant and method for generating hot water - Google Patents

Description

15 includes a control valve which regulates the flow of district heating water through the heat exchanger device on its primary side.

This control valve can be arranged to be controlled electronically by means of an electronic control unit in dependence on measured values from a temperature sensor which senses the temperature of the generated domestic hot water leaving the heat exchanger device. Alternatively, the control valve can be direct-acting and mechanically controlled by the temperature of the generated domestic hot water, for example via a heat-carrying medium which is affected by the temperature of the generated domestic hot water.

The heat-carrying district heating water in the supply line of a Swedish district heating network usually has a temperature between about 65-100 ° C, with the lower temperature of about 65 ° C being applied during the warmer part of the year and the higher temperature of about 100 ° C being applied during the colder part of the year. A district heating system must therefore be dimensioned taking into account this temperature variation between approximately 65-100 ° C of the district heating water. Especially in the case where the district heating water is at the higher temperature level of about 100 ° C, it is difficult in a conventionally designed district heating system to regulate the temperature of the domestic hot water with such precision that hot temperature peaks with scalding risk of the domestic hot water are avoided. Under these circumstances, namely, flow changes of the domestic hot water on the secondary side of the heat exchanger must immediately result in changes in the flow of the district heating water on the primary side of the heat exchanger in order to maintain the desired target temperature of the domestic hot water. To cope with this, advanced and fast control equipment of a costly type is required. Thus, difficulties in maintaining the temperature of the domestic hot water at the desired target temperature can arise in connection with flow changes of the domestic hot water on the secondary side of the heat exchanger device. Difficulties in maintaining the temperature of the domestic hot water at the desired target temperature can also arise in connection with temperature peaks or temperature drops of the district heating water on the primary side of the heat exchanger rat due to flow changes in the district heating network's supply line.

In a countercurrent heat exchanger, the medium in the primary circuit of the heat exchanger and the medium in the secondary circuit of the heat exchanger are arranged to flow in opposite directions so that they meet each other, which gives a very efficient heat exchange where the medium flowing through the secondary circuit can reach an outlet temperature. is just below the inlet temperature of the medium flowing through the primary circuit while the medium flowing through the primary circuit can reach an outlet temperature just above the inlet temperature of the medium flowing through the secondary circuit. In a co-current-connected heat exchanger, the medium in the primary circuit of the heat exchanger and the medium in the secondary circuit of the heat exchanger are arranged to flow next to each other in the same direction, which gives a more moderate heat exchange where the temperature of each medium goes towards a temperature of the medium flowing through the primary circuit and the inlet temperature of the medium flowing through the secondary circuit. Since countercurrent heat exchangers provide the most efficient heat exchange, such heat exchangers are generally used in conventional district heating systems.

OBJECT OF THE INVENTION The object of the present invention is to provide a district heating system with a new and advantageous design which creates good possibilities for a satisfactory control of the temperature level of the domestic hot water generated in the district heating system.

SUMMARY OF THE INVENTION According to the present invention, said object is achieved by means of a district heating plant having the features defined in claim 1. The district heating system according to the invention comprises: - a first inlet intended to be connected to a supply line of a district heating network for receiving district heating water from the district heating network, - a second inlet intended to be connected to a cold water line for receiving cold water, - a heat exchanger device connected to said first and second inlets for generating domestic hot water by transferring heat from the district heating water to the cold water, - a first outlet connected to the heat exchanger device, which is intended to be connected to a return line of the district heating network for return heating to the district heating network. sage through the heat exchanger installation, - a second outlet connected to the heat exchanger installation, which is intended to be connected to a domestic hot water line for the discharge of domestic hot water generated during the passage of cold water through the heat exchanger installation, - a first heat exchanger device included in the heat exchanger installation exchangers for preheating hot water, said first heat exchanger being countercurrently connected and having a primary circuit connected to said first outlet for supplying district heating water thereto and a secondary circuit connected to said second inlet for receiving cold water therefrom, and - a second heat exchanger included in the heat exchanger device for final heating of domestic hot water, this second heat exchanger being connected to a co-current and having a secondary circuit which is connected to the secondary circuit of the first heat exchanger to receive preheated domestic hot water to drain hot water from this this, and a primary circuit, which is connected between said first inlet and the primary circuit of the first heat exchanger so that the district heating water flowing through the heat exchanger device is passed through the primary circuit of the second heat exchanger on its way between said first inlet and the first heat exchanger i- mark circuit. Thus, in the above-mentioned heat exchanger device, the incoming cold water will first be passed through the secondary circuit of the countercurrently connected first heat exchanger while absorbing heat from the district heating water in the primary circuit of this first heat exchanger for an initial increase in water temperature. . The preheated domestic hot water is then passed through the secondary circuit of the co-current-connected second heat exchanger while absorbing heat from the district heating water in the primary circuit of this second heat exchanger for a final heating of the domestic hot water to the desired target heating, a so-called final heating.

Because the second heat exchanger is connected to co-current instead of to counter-current, the final heating of the domestic hot water takes place in a relatively slow process. This facilitates the control of the temperature of the generated domestic hot water, which entails a reduction in the requirements for the control equipment used for this control. The fact that the final heating takes place in a heat-exchanged heat exchanger is also ensured that the generated domestic hot water cannot reach a dangerously high temperature which is close to the temperature of the district heating water flowing into the other heat exchanger, thus reducing the risk of scalding. With the solution according to the invention, it thus becomes possible to use control equipment that is simpler and cheaper than the control equipment required in a conventionally designed district heating system, while at the same time reducing the risk of unwanted and risky temperature peaks in the generated domestic hot water.

According to an embodiment of the invention, the heat exchanger device also comprises a co-current-connected third heat exchanger having: - a primary circuit connected to said first inlet for receiving district heating water therefrom and to the primary heat exchanger of the second heat exchanger for supplying district heating water, a secondary circuit connected to the primary circuit of the second heat exchanger for receiving district heating water therefrom and to the primary circuit of the first heat exchanger for supplying district heating water thereto.

The incoming district heating water will in this case first be led through the primary circuit of the third heat exchanger during heat exchange with the district heating water in the secondary circuit of this third heat exchanger and then, in turn: - through the primary circuit of the second heat exchanger during discharge. the hot water in the secondary circuit of this second heat exchanger to thereby bring about final heating of the hot water, - through the secondary circuit of the third heat exchanger during heat exchange with the district heating water in the primary circuit of this third heat exchanger by the first heat exchanger; to the cold water in the secondary circuit of this first heat exchanger to thereby cause preheating of the domestic hot water and the required cooling of the district heating water.

With the aid of the above-mentioned third heat exchanger, a significant reduction of the temperature variations of the district heating water is achieved in the part of the heat exchanger installation where the incoming district heat water first comes into heat transfer contact with the water to be heated for generating domestic hot water, ie. at the inlet to the primary circuit of the heat exchanger where the final heating of the domestic hot water takes place. In the “high temperature case” when the temperature of the district heating water in the district heating supply line is at the higher temperature level of about 100 ° C, the temperature of the incoming district heating water passing through the third heat exchanger's primary circuit will be lowered to a greater extent by heat exchange with the cooler district heating water passing through the secondary circuit of the third heat exchanger than in the "low temperature trap" when the temperature of the district heating water in the supply line of the district heating network is at the lower temperature level of about 65 ° C, thus leading to a reduction in temperature difference the high temperature drop and the low temperature drop with respect to the temperature of the district heating water at the inlet to the primary circuit of the heat exchanger where the final heating of the domestic hot water takes place, thereby facilitating the regulation of the temperature of the generated domestic hot water. reduction of requirements on the control equipment used for this control. In addition, heat exchange between the incoming district heating water passing through the third circuit of the third heat exchanger and the district heating water passing through the secondary circuit of the third heat exchanger reduces the temperature peaks and temperature drops that result from changes in flow in the district heating network. This also facilitates the regulation of the temperature of the generated domestic hot water and contributes to a reduction in the requirements for the control equipment used for this regulation.

Other advantageous features of the district heating system according to the invention appear from the dependent claims and the following description.

The invention also relates to a method for generating domestic hot water having the features defined in claim 6.

BRIEF DESCRIPTION OF THE DRAWINGS The invention will be described in more detail below with the aid of exemplary embodiments, with reference to the accompanying drawings.

It is shown in: Fig. 1 a wiring diagram illustrating a district heating system according to a first embodiment of the present invention, Fig. 2 a wiring diagram illustrating a district heating system according to a second embodiment of the invention, and Fig. 3 a wiring diagram illustrating a district heating system according to a third embodiment of the invention.

DETAILED DESCRIPTION OF PREFERRED EMBODIMENTS Fig. 1 illustrates a district heating system 10 according to an embodiment of the present invention intended for providing domestic hot water in a building, such as for example in a residential house in the form of a villa or an apartment building. The district heating system 10 is schematically indicated by a broken line in Fig. 1 and comprises: - a first inlet 11 connected to an inlet line 1 of a district heating network for receiving district heating water from the district heating network, - a second inlet 12 connected to a cold water line 2 for receiving cold water collection, - a heat exchanger device 13 connected to said first and second inlets 11, 12 for generating domestic hot water by transferring heat from the district heating water to the cold water, - a first outlet 14 connected to the heat exchanger device 13, which is connected to a return line 3 of the district heating network for returning district heating water to the district heating network after its passage through the heat exchanger device 13, and - a second outlet 15 connected to the heat exchanger device 13, which is connected to a hot water line 4 for discharging tap hot water generated by cold water passage through the heat exchanger device 13.

Via the hot water line 4, the hot water generated by the heat exchanger device 13 is led to one or more tapping points 5, which may, for example, be provided with hot water taps.

In the embodiments illustrated in Figs. 1 and 2, the heat exchanger device 13 comprises two heat exchangers 20, 30. A first heat exchanger 20 included in the heat exchanger device 13 is intended for preheating domestic hot water. In this first heat exchanger 20 there is thus an initial increase of the temperature of the cold water flowing into the heat exchanger device 13. This first heat exchanger 20 is countercurrently connected and has: a primary circuit 21 which is connected to said first outlet 14 of the district heating system for delivering to this outlet 14 district heating water which is cooled during its passage through the heat exchanger device, and - a secondary circuit 22 which is connected to said second inlet 12 of the district heating system for receiving cold water from the cold water line 2 via this inlet 12.

A second heat exchanger 30 included in the heat exchanger device 13 is intended for final heating of domestic hot water. In this second heat exchanger 30, a final increase of the temperature of the water flowing through heat exchanger device 13 on its secondary side thus takes place, so that hot water is thereby generated at the desired temperature. This second heat exchanger 30 is connected to a co-current and has: - a primary circuit 31 which is connected to said first inlet 11 of the district heating plant for receiving district heating water from the district heating network supply line 1 via this inlet 11 and to the first heat exchanger's primary circuit 21 for , and - a secondary circuit 32 connected to the secondary circuit 22 of the first heat exchanger for receiving preheated domestic hot water from it and to said second outlet 15 of the district heating plant for supplying final hot domestic hot water to the hot water line 4 via this outlet 15.

In the embodiments illustrated in Figs. 1 and 2, the primary circuit 31 of the second heat exchanger and the primary circuit 21 of the first heat exchanger together form the primary side of the heat exchanger device, while the secondary circuit 22 of the first heat exchanger and the secondary heat exchanger of the second heat exchanger. secondary side. In the district heating plants 10 according to Figs. 1 and 2, incoming cold water from the cold water line 2 is led through the secondary circuit 22 of the countercurrently connected first heat exchanger '10 15 20 25 30 35 10 20 while absorbing heat from district heating water in the primary circuit 21 of this heat exchanger. providing preheating hot water, after which the preheated hot water is passed through the secondary circuit 32 of the co-current second heat exchanger 30 while absorbing heat from district heating water in the primary circuit 31 of this heat exchanger to thereby achieve the desired temperature. C. The incoming district heating water from the district heating network supply line 1 is led through the primary circuit 31 of the second heat exchanger 30 while supplying heat to the preheated domestic hot water in the secondary circuit 32 of this heat exchanger to effect said final heating of the tap. The district heating water is then passed through the primary circuit 21 of the first heat exchanger 20 while supplying heat to the cold water in the secondary circuit 22 of this heat exchanger to effect said preheating of the domestic hot water and a cooling of the district heating water to a temperature of 22 ° C. 3 of the district heating network.

In the embodiment illustrated in Fig. 3, the heat exchanger device 13 also comprises a third heat exchanger 40. The embodiment according to Fig. 3 otherwise corresponds to the embodiment according to Fig. 1. This third heat exchanger 40 is arranged to provide an initial influence on the temperature of the heat exchanger. district heating water flowing into the heat exchanger device 13 so that the temperature variations of this district heating water are damped before the district heating water reaches the second heat exchanger 30 where the final heating of the domestic hot water takes place. This third heat exchanger 40 is connected to a co-current and has: - a primary circuit 41 which is connected to said first inlet 11 of the district heating system for receiving district heating water from the district heating network supply line 1 via this inlet 11 and to the second heat exchanger's primary circuit 31. , and - a secondary circuit 42 connected to the primary circuit 31 of the second heat exchanger for receiving district heating water therefrom 11 and to the primary circuit 21 of the first heat exchanger for supplying district heating water thereto.

Thus, in the third heat exchanger 40, a heat exchange takes place between the incoming district heating water which has not yet given off any heat to the water on the secondary side of the heat exchanger device and the district heat water which has passed through the second heat exchanger 30 during heat exchange to the water on the secondary heat exchanger.

In the embodiment illustrated in Fig. 3, the primary circuit 41 of the third heat exchanger, the primary circuit 31 of the second heat exchanger, the secondary circuit 42 of the third heat exchanger and the primary circuit 21 of the first heat exchanger together form the heat exchanger device 22 of the primary heat exchanger device 22. the first heat exchanger and the secondary circuit 32 of the second heat exchanger together form the secondary side of the heat exchanger device. In the district heating plant 10 according to Fig. 3, incoming cold water from the cold water line 2 is led through the secondary circuit 22 of the countercurrently connected first heat exchanger 20 while absorbing heat from district heating water in the primary circuit 21 of this heat exchanger to thereby cause preheating, preheating and hot water. the domestic hot water is passed through the secondary circuit 32 of the co-connected second heat exchanger 30 while absorbing heat from district heating water in the primary circuit 31 of this heat exchanger to thereby effect final heating of the domestic hot water to the desired target temperature of about 55 ° C.

The incoming district heating water from the district heating network's supply line 1 is led, in turn: through the primary circuit 41 of the third heat exchanger 40 during heat exchange with district heating water in the secondary circuit 42 of this heat exchanger, - through the primary circuit 31 of the second heat supply to the second heat exchanger. the preheated domestic hot water in the secondary circuit 32 of this heat exchanger to effect said final heating of the domestic hot water, - through the secondary circuit 42 of the third heat exchanger 40 during heat exchange with district heating water in the primary heating circuit and the primary circuit 41 21 of the first heat exchanger 20 while supplying heat to the cold water in the secondary circuit 22 of this heat exchanger to effect said preheating of the domestic hot water and a cooling of the district heating water to a temperature of 22 ° C or lower, after which the district heating water 3 is returned to the return water .

Each of the above-mentioned heat exchangers 20, 30, 40 of the heat exchanger device 13 is of the recuperative type, i.e. so designed that the water flows through the primary circuit of the heat exchanger without mixing with the water present in the secondary circuit of the heat exchanger.

In the embodiment illustrated in Fig. 2, the district heating system 10 is provided with a return line 16, via which the generated domestic hot water is returned to the secondary circuit 32 of the second heat exchanger 30 so that the domestic hot water can be circulated in a circulation circuit through the secondary heating circuit 32 of the secondary heating circuit 32. and hot water line 4. In this case, the district heating system 10 is provided with a circulation pump 17 which is arranged to ensure the circulation of tap hot water in said circulation circuit. A non-return valve 18 prevents preheated hot water from flowing from the first heat exchanger 20 directly to the hot water line 4 without first passing through the second heat exchanger 30. In the illustrated example, the circulation pump 17 and the non-return valve 18 are arranged in the return line 16. With with the help of the circulation circuit it becomes possible to ensure an immediate supply of hot water of correct temperature at the tapping points 5. In the case where the district heating system 10 does not have a return line 16 for circulating the hot water, it may take a short time before hot water of correct temperature reaches a tapping point 5 after a hot water tap at the tapping point has been opened. With the exception of the return line 16, the embodiment 10 according to Fig. 2 corresponds to the embodiment according to Fig. 1. Of course, a district heating system of the type illustrated in Fig. 3 can also be provided with a return line of the type described above for circulation of the generated domestic hot water.

A non-return valve 19 is arranged in the line L1 between the second inlet 12 and the first heat exchanger 20 to ensure a correct flow direction of the water through the secondary side of the heat exchanger device.

The heat transfer in the heat exchanger device 13 and thereby the temperature of the generated domestic hot water is controlled by means of a control equipment, which comprises a control valve 50 which regulates the flow of district heating water on the primary side of the heat exchanger device. In the illustrated embodiments, this control valve 50 is arranged to be controlled electronically by means of an electronic control unit 51 in dependence on measured values from a temperature sensor 52 which is arranged to sense the temperature of the domestic hot water on the secondary side of the heat exchanger device. The control unit 51 is arranged to receive temperature information from the temperature sensor 52 and control the control valve 50 depending on this temperature information so that the heat dissipation from the district heating water on the primary side of the heat exchanger device to the water on the secondary side of the heat exchanger device is kept at such a level that the final heat the exchanger 30 is made to pour the desired melting temperature, which is usually at about 55 ° C. Alternatively, the control valve can be direct-acting and mechanically controlled by the temperature of the domestic hot water, for example via a heat-carrying medium which is affected by the temperature of the domestic hot water. In the illustrated examples, the temperature sensor 52 is arranged to sense the temperature of the preheated domestic hot water upstream of the secondary circuit 32 of the second heat exchanger, i.e. in the line L2 between the first heat exchanger 20 and the second heat exchanger 30. The temperature sensor could alternatively be arranged sensing the temperature of the final heated domestic hot water downstream of the second heat exchanger secondary circuit 32, i.e. in the line L3 between the second heat exchanger 30 said second outlet 15. In the case where the district heating system lacks a return line of the type illustrated in Fig. 2 for circulation of the generated hot water, a flow monitor (not shown) can be arranged in a manner known per se when sensing the tapping of hot water begins. When the flow monitor detects an initiated water flow, it sends a signal to the control unit 51 to open the control valve 50 to thereby begin the generation of domestic hot water.

The invention is of course in no way limited to the embodiments described above, but a number of possibilities for modifications thereof should be obvious to a person skilled in the art, without this for that reason deviating from the basic idea of the invention as defined in the appended claims. . The district heating system according to the invention could, for example, also be provided with a heat exchanger device for transferring heat from district water to a local heating system in a building for heating, for example, indoor air in the building.

Claims (1)

15 PATENT REQUIREMENTS A district heating plant comprising: a first inlet (11) intended to be connected to an inlet line of a district heating network for receiving district heating water from the district heating network, - a second inlet (12) intended to be connected to a cold water line for receiving cold water, - a heat exchanger device (13) connected to said first and second inlets (11, 12) for generating domestic hot water by transferring heat from the district heating water to the cold water, - a first outlet (13) connected to the heat exchanger device (13) 14), which is intended to be connected to a return line of the district heating network for the return of district heating water to the district heating network after its passage through the heat exchanger device (13), - a second outlet (15) connected to the heat exchanger device (13), which is intended to connected to a domestic hot water line for the discharge of domestic hot water generated during the passage of cold water through the heat exchanger device (13), and - one in heat the heat exchanger device (13) comprising first heat exchanger (20) for preheating domestic hot water, said first heat exchanger (20) being countercurrently connected and having a primary circuit (21) connected to said first outlet (14) for supplying district heating water thereto and a secondary circuit (22) connected to said second inlet (12) for receiving cold water therefrom, characterized in that the heat exchanger device (13) also comprises a co-current-connected second heat exchanger (30) for final heating of domestic hot water, this second heat exchanger (30) has: - a secondary circuit (32) connected to the secondary circuit (22) of the first heat exchanger for receiving preheated domestic hot water from it and to said second outlet (15) for supplying final hot domestic hot water thereto , and - a primary circuit (31) connected between said first inlet (11) and the primary circuit (21) of the first heat exchanger so that district heating water flowing through the heat exchanger device The ring (13) is caused to pass through the primary circuit (31) of the second heat exchanger on its way between said first inlet (11) and the primary circuit (21) of the first heat exchanger. . District heating plant according to claim 1, characterized in that the heat exchanger device (13) also comprises a co-current-connected third heat exchanger (40) having: - a primary circuit (41) connected to said first inlet (11) for receiving district heating water from this and to the primary circuit (31) of the second heat exchanger for supplying district heating water thereto, and - a secondary circuit (42) connected to the primary circuit (31) of the second heat exchanger for receiving district heating water therefrom and to the first heat exchanger primary circuit (21) for supplying district heating water to it. . District heating plant according to Claim 1 or 2, characterized in that the district heating plant (10) comprises: - a temperature sensor (52) which is arranged to sense the temperature of preheated domestic hot water upstream of the second heat exchanger's secondary circuit (32) or the temperature of the final hot tap. the secondary circuit (32) of the heat exchanger, and - a control valve (50) for regulating the flow of district heating water through the heat exchanger device (13), this control valve (50) being arranged to be controlled depending on the temperature sensed by the temperature sensor (52). . . District heating plant according to Claim 3, characterized in that the temperature sensor (52) is arranged to sense the temperature of preheated domestic hot water upstream of the secondary circuit (32) of the second heat exchanger. . District heating plant according to Claim 3 or 4, characterized in that the district heating plant (10) comprises an electronic control unit (51) for controlling the control valve (50), this control unit (51) being arranged to receive temperature information from the radiator. 17 the temperature sensor (52) and control the control valve (50) depending on this temperature information. . A method for generating domestic hot water, wherein - cold water is passed through a secondary circuit (22) of a countercurrently connected first heat exchanger (20) during the absorption of heat from district heating water in a primary circuit (21) of the first heat exchanger (20) to thereby causing preheating of domestic hot water, after which the preheated domestic hot water is passed through a secondary circuit (32) of a co-current-connected second heat exchanger (30) while absorbing heat from district heating water in a primary circuit (31) of the second heat exchanger (32) thereby effecting final heating of the domestic hot water, and - district heating water is received from a supply line (1) of a district heating network and passed through the primary circuit (31) of the second heat exchanger (30) before being passed through the primary circuit (21) of the first heat exchanger ), after which the district heating water is discharged to a return line (3) of the district heating network. Method according to claim 6, wherein the district heating water received from the supply line (1) of the district heating network is led, in turn, through a primary circuit (41) of a co-current-connected third heat exchanger (40), through the primary circuit (31) of the second heat exchanger (30). ), through a secondary circuit (42) of the third heat exchanger (40) and through the primary circuit (21) of the first heat exchanger (20), after which the district heating water is supplied to the return line of the district heating network.