SE450855B - Heat pumps for heating system - Google Patents

Abstract

Two or more heat pumps (12-14) are used to transmit heat energy from a source (11) at low temp. to a return conduit (10). At least one heat pump (12) is held connected between the heat source and the return conduit with low heat requirement, whilst another (14) is connected similarly for high heat requirement. The latter pump is connected in the return conduit between upstream and downstream points if the other pumps are connected between the source and the return conduit with average heat requirement in the installation.

Description

15 20 25 30 45Û 855 tent requirements.

By keeping a heat pump connected between the heat source and the return line and a heat pump connected in the return line between a point upstream and a point downstream of the heat pump, which is connected between the heat source and the return line, at medium heat demand in the heating system, ie during spring and autumn, the heat factor of the heat pumps is improved, ie the ratio between emitted heat energy and supplied energy, usually electrical energy, for operation of the pump, which results in improved efficiency of the heat pumps and better operating economy in the plant. Because the heat pumps consist of a low-temperature heat pump and a high-temperature heat pump, particularly favorable operating conditions are obtained.

An embodiment of the method according to the invention will now be described in more detail below with reference to the accompanying drawing, which schematically shows the transfer of heat energy from a sewage line to a return line in a heat plant by means of heat pumps.

The plant schematically shown in the drawing comprises a return line 10 to a heating plant. This return line transports a circulating, heat-carrying medium, usually water, back to the boiler in the heating system for re-heating. The return line 10 is supplied with heat from a line 11, which transports wastewater to a treatment plant, by means of three heat pumps 12,13,14. Of these heat pumps, the pumps 12 and 13 are of the low temperature type and the pump 14 of the high temperature type. The heat-carrying media in lines 10 and 11 flow from left to right in the figure, as indicated by arrows.

The heat pumps 12 and 13 are with their heat-absorbing sides connected to the line 11 and with their heat-emitting sides connected to the line 10, so that they can always transfer heat from the drain line 11 to the return line 10. The heat-absorbing side of the heat pump 14 is arranged to be connected either to the line 11 through the connecting lines 18,19 or over a heat exchanger 15 to the hinge. 10 15 20 25 30 35 450 855 10 upstream of the heat pumps 12 and 13. The connection is made by means of valves 16,17, which are designed so that they also enable connection of the heat-absorbing side of the heat exchanger 14 to both lines 10,11. at the same time. The heat-emitting side of the heat pump 14 is connected to the line 10 downstream of the heat pumps 12 and 13 by means of the connecting lines 20, 21.

The facility shown and described is operated in the following manner. If there is little heat demand in the heating system, ie during summer time, only the high-temperature heat pump 14 is used, which is then connected between the drain line 11 and the return line 10 by means of the connecting lines 18, 19 and 20, 21, respectively. The temperature of the water in the sewer is about IO-11 ° C, and the high-temperature heat pump gives a temperature of about 85 ° C on its heat-dissipating side. This temperature is high enough for the high-temperature heat pump 14 alone to be able to supply the required heat supply to the heating system, provided that the heat pump 14 is dimensioned to be able to emit a heating effect that corresponds to the heating system's total heat demand during summer time. , and that the sewer line can emit a sufficient amount of waste heat. These two conditions can be met without difficulty, as high-temperature heat pumps with the required output power are available on the market and the wastewater from at least medium-sized communities can provide a sufficient amount of waste heat.

In the event of a large heat demand in the heating system, ie during the winter, the available amount of waste heat is not sufficient, and the heat pumps can then only raise the temperature in the return line to around 60 ° C. Additional heat must therefore be supplied to the heating system, for example by burning oil. For maximum utilization of the waste heat source, the heat pumps 12,13,14 should in this case be connected between the drain line and the return line. The heat pumps 12,13 are of the low-temperature type, since such heat pumps have a better heat factor than high-temperature pumps. Namely, the heat factor falls rapidly with increasing difference between the inlet temperature and the outlet temperature. When the heat factor decreases, the costs per given Mwh for the heat pumps increase. It is therefore more suitable for relatively large heat systems to use several heat pumps with different temperature increase stages 1 than a single large heat pump, which lifts all waste heat to the island at least 80 ° C. In the event of a medium-sized heat demand in the heating system, ie during spring and autumn, the available waste heat in the sewer line is sufficient to cover the heating system's needs. If in this case all the heat pumps are connected between the drain line and the return line, the capacity utilization in each pump will be relatively low, which results in low efficiency, ie low heat factor. The best efficiency is obtained with a capacity utilization between 70% and 100% of the pumps' heat output. Using only two of the heat pumps does not provide maximum utilization of the available waste heat energy. In this position, according to the invention, it is more favorable to connect a heat pump, preferably the high temperature heat pump 14, in the return line 10 in such a way that the position temperature side of the pump, i.e. the heat absorbing side, is switched upstream and the high temperature side of the pump, ie the heat dissipating side, is switched downstream the drain line 11 and the return line 10 connected the heat pumps 12,13. The high temperature pump 14 will then have an inlet temperature of about 40 ° C, which is a normal temperature in the return line 10, and an outlet temperature of eg 85 ° C. This results in a significantly better heating factor of the heat pump 14 than if the heat pump were to be connected between the drain line 10 and the return line 11 and operate with a temperature difference of about 70 ° C, ie from 10 ° C to BOPC. In addition, the stated connection of the high temperature heat pump 14 that the temperature in the return line is lowered, before it reaches the point where the low-temperature heat pumps 12,13 are connected, which means that the heat capacity of the two low-temperature heat pumps increases, so that the waste heat source is utilized to the maximum 10 15 25 30 35 450 855 14 in the return line 10, when the heat demand in the heating system is medium, results in more favorable operating conditions for the heat pumps, which in turn provides significant cost savings. The temperature in a waste water line of the type specified here can be around 11 "C If the heat pump 14 is connected to the waste water line 11, the temperature in the waste water line will ne dstream of the heat pump to be about 10 ° C. Downstream of the heat pump 13 the temperature will then be about 6 ° C, and downstream of the heat pump 12 the temperature will be about 2 ° C.

The choice of refrigerant in the heat pumps depends on the temperature of the waste heat source and on the temperature at which the heat is to be delivered. Different refrigerants have different operating temperature ranges and give different output powers and consequently different costs, as shown in the following table: »refrigerant temperature range relative output power% krlkw R 22 10 ° C | 45-60“ C 100 100 R 12 10 ° Ci70-80 ° C 70 '140 R 114 10 ° C | 70-105 ° C 25 400 R 114 40 ° Ci70-105 ° C 50 200 Thus, if the waste heat temperature is raised from 10 ° C to 40 ° C, the heat pump power increases to about twice that. This condition is used in the method according to the invention.

For the refrigerant R 114, the limitation applies that the temperature of the waste heat source should not be lower than about 8 ° C. To cope with this limitation and to counteract the low efficiency of the heat pump, when the temperature is close to the critical value, the heat pump 14, which is the heat exchanger in which this refrigerant can be used, can be connected both to the drain line 11 and to the return line. Simultaneously through the valves 16,17, so that heat can be transferred from the return line 10 to the heat-absorbing side of the heat pump 14, when the temperature of the waste heat source is close to the critical value. The heat exchanger 15 is connected between the return line 10 and the heat-absorbing side of the heat pump 14 to prevent the mixing of dirty waste water in the water of the return line.

Since it is appropriate to use several heat pumps with different temperature working areas, it may also be appropriate to change the working areas of the heat pumps at special times by changing the refrigerant. Various refrigerants can give operating temperatures on the heat dissipating sides of the heat pumps between 45 ° C and 105 ° C. Although only one embodiment has been shown and described, it is obvious that many variations and modifications are possible within the scope of the inventive concept. The heat pump, which is connected to the return line on both sides, does not necessarily have to be of the high-temperature type, but such a pump is more advantageous in this context than a low-temperature heat pump, because it provides a greater cost saving. a heat pump of the low-temperature type between the drain line and the return line, when the heat demand in the heating system is medium-sized. Furthermore, several pumps of the same or different types can be connected in the return line or between the drain line and the return line. Finally, other types of waste heat sources than wastewater can also be used, such as seawater and outdoor air. -nl

Claims (8)

10 20 30 450 ass Patent claim 1. A method for utilizing the heat energy in low temperature energy sources such as additional energy in the operation of a heating plant, which for the heat transport uses a heat-carrying medium which is returned to the heating plant through a return line (10), wherein two or several heat pumps (12, 13, 14) are used for transferring heat energy from a low temperature heat source (11) to the return line (10) in such a way that at least one heat pump (14) is kept connected between the heat source (11) and the return line (10) at low heat demand in the heating system and that at least one additional heat pump (l2, l3) is connected between_the heat source (ll) and the return line (10) at high heat demand in the heating system, characterized in that at medium heat demand in the heating system one (14) of the heat pumps is connected to the return line (10) with its heat-absorbing side connected upstream and with its heat-dissipating side connected downstream if the sleeve pumps (l2, l3), which are connected between the heat source (ll) and the return line (10). Method according to Claim 1, characterized in that the heat pump which is connected in the return line (10) in dependence on the heat demand in the heating system is constituted by a high-temperature heat pump (14). Method according to claim 2, characterized in that the high-temperature heat pump (14) is dimensioned to meet the total heat demand in the event of a small heat demand in the heating system. Method according to Claim 2 or 3, characterized in that the heat pump, which is connected between the heat source (II) and the return line (10) in the event of a large heat build-up in the heating system, consists of a low-temperature heat pump (12). Method according to Claim 4, characterized in that a further low-temperature heat pump (13) is connected between the heat source (11) and the return line (10). Method according to one of the preceding claims, characterized in that the refrigerant in one or more of the heat pumps (12, 13, 14) is exchanged for varying the temperature working ranges of the heat pumps. U _ Method according to one of the preceding claims, characterized in that a heat exchanger (15) is connected between the return line (10) and the heat-absorbing side of the heat pump (14). Method according to claim 7, characterized in that the heat-absorbing side of the heat pump (14) is connected to the heat exchanger (15) and to the heat source (11) in such a way that heat can be transferred simultaneously from the return line (10) and from the heat source (11). to the heat pump (14). di!