UA25689U - Installation for consumer supply with heat energy - Google Patents

Abstract

Installation for supply of consumers with heat energy has outlet line of heated at least in one heat source heat carrier, at that outlet line is connected to input of at least one distribution unit corresponding to it, this is arranged with multiple outputs, to those supply lines to heat energy consumers are connected, with different temperature levels, at that distribution unit is arranged with possibility to choose one of consumers for supply of heated heat carrier.

Description

Description of the invention

The utility model belongs to installations for supplying consumers with thermal energy of 2 coolants, heated in at least one heat source.

To supply consumers with thermal energy, it is known to use environmental heat collectors, such as solar collectors, waste heat collectors, Earth heat collectors, etc. It is also known that in order to achieve the temperature level corresponding to the requirements of thermal energy consumers, such thermal energy, which has a low temperature, is brought with the help of heat pumps to thermal energy with a high temperature 70 IZO 1537978, 5 1695054, 5) 935681). But when supplying consumers with thermal energy, many circumstances have to be taken into account, and therefore the installations known so far do not meet the technical and organizational requirements, and the use of such installations has narrow limits.

Thus, the efficiency of environmental heat collectors, in particular solar collectors, is high when the coolant is supplied to these collectors with the lowest possible temperature, because only due to this, with the help of environmental heat collectors, a large temperature difference can be used, thanks to which it is possible to obtain a large amount of thermal energy. But at the same time, you should pay attention to the fact that in a large number of environmental heat collectors, the supply of heat changes over time. Thus, the thermal energy that can be obtained in the ambient heat collectors depends on the given external temperature, which is much higher in summer than in winter, and during the day, as a rule, higher than at night.

Further, the thermal energy that can be obtained with the help of solar collectors depends on the given solstice relative to the solar collector, as well as atmospheric conditions. The same conditions apply to such heat collectors, which are used to receive waste heat from production processes or processing processes, since the supply of heat depends on the duration of these processes. Accordingly, the difficulty lies in the fact that the time intervals of heat supply by thermal collectors do not coincide with the time intervals of heat demand by thermal energy consumers, which can cause, on the one hand, an excessive supply of thermal energy produced by thermal collectors, and on the other hand, heat consumption that is not covered by heat collectors. Further, it should be taken into account that different heat collectors, such as solar collectors, ambient heat collectors or heat accumulators, give off coolants with different temperature levels at the same time, therefore coolants given off by separate heat sources cannot in any case be mixed with each other , because otherwise the coolant with the highest temperature level c would cool down to a lower temperature level, which would lead to a loss of heat potential. Accordingly, it is necessary to ensure that, flowing from different heat sources, coolants with different temperature levels are directed to those consumers of thermal energy that are designed for these temperature levels. Since this temperature level is raised with the help of a heat pump to a higher temperature level, with that

So that due to this it is possible to send to certain consumers the thermal energy required by them, with a high temperature level, it is necessary to further consider that the efficiency of heat pumps! high when a coolant with a temperature value lying within narrow limits is supplied to them. In addition, heat pumps are required to remain on continuously for long periods of time, at least one hour, or to exclude frequent switching on and off of heat pumps, because otherwise their service life would be drastically reduced. . At the same time, it should also be taken into account that the maximum power of heat pumps should be calculated so that even with a low supply of thermal energy, from the ambient heat received in the collectors, it is possible to cover the need for thermal energy.

In such installations, it should also be taken into account that in buildings, in particular, hotels, residential buildings, industrial enterprises and production facilities, there is a need not only for heat, but also for cooling energy. Thermal energy is more needed in the cold season, in particular in winter for heating, and throughout the year for heating technical water for cleaning purposes, swimming pools, air conditioning of rooms, etc. sl Refrigeration energy is needed throughout the year for refrigeration purposes, for example in refrigeration units for food storage. Since such installations are usually located in the central parts of buildings, it has been observed that the need for cooling energy in winter is at least as great or even 20 times greater than in summer. The reason for this is that such buildings are heated in winter, and this heating energy also enters the cold rooms. c The useful model is based on the task of creating an installation for supplying consumers with thermal energy with a heat carrier heated in at least one heat source, which takes into account a large number of the above circumstances, thanks to which the proposed installation ensures timely, high-quality and economical use of 25 heat carriers and the supply of heat to consumers. c The task is solved by the fact that the installation for supplying consumers with thermal energy contains the output line of the coolant heated in at least one heat source (A, B), and the output line is connected to the input of at least one distribution device corresponding to it (1, 2) , made with many outputs, to which supply lines (71-79) are connected to consumers of thermal energy with different 60 temperature levels, while the distribution device (1, 2) is made with the possibility of choosing one of the consumers to supply the heated coolant. At the same time, it can be provided: thermal energy consumers with different temperature levels are connected in series to ensure consistent washing with the coolant; at least one heat source is made in the form of a solar collector (A, B); because at least one heat source is made in the form of a heat collector of the environment or an accumulator of the Earth's heat, etc.; at least two solar collectors (A, B) oriented in different directions; at least one heat source is made in the form of a heat pump (8); return lines (Uba - 79da) of consumers with a low temperature level are connected to the inlets of the collector device (6), made with a single output line (60), which is connected to the input of the heat pump (8), and with the help of the collector device (b) they choose that consumer, the return line of which is connected to the heat pump (8); the return lines of heat energy consumers with a low temperature level are connected through the collector 70 device (6) to the evaporator (81) of the heat pump (8), and the return lines of heat energy consumers with a high temperature level are connected through the additional collector device (5) to the condenser (84 ) heat pump (8); the output of the heat pump (8) is connected to the input of an additional distribution device (3), made with many outputs leading to consumers with a high temperature level, and with the help of this additional distribution device (3) one of the consumers is selected, to which from the heat pump (8) /5 feed coolant; the heat pump (8) is made with an evaporator (81), a compressor (83) and a condenser (84), and a cooling energy consumer (9) is connected to the evaporator (81); the return line (90) of the consumer (9) of cooling energy is connected to the input of an additional distribution device (4), to the outputs of which consumers with a low temperature level are connected, and with the help of this additional distribution device (4) one of the consumers is selected, to which the heated in the consumer (9) of cooling energy of the coolant; the return line of the consumer (9) of cooling energy is connected to the mixing valve (85), to which the lines leading to the heat collectors (A, B) and to the evaporator (81) of the heat pump (8) are connected.

The essence of the useful model is explained with the help of the installation diagram shown in fig.

The installation contains two distribution devices 1, 2, to the single inputs of which the output lines 10, 20 of two heat sources are connected. Sources of heat are, for example, environmental heat collectors, in particular o, solar collectors A, B, waste heat collectors, Earth heat accumulators, etc. Lines 11-19 are connected to the outputs of distribution devices 1, 2. 21-29 are connected to supply lines 71-79 for thermal energy consumers with different temperature levels. Return lines 71a-79a from consumers are connected respectively to Ge! zo to the supply lines of the next thermal energy consumer. So, the return line 71 and is connected to the supply line 72 for the second heat energy consumer. Supply lines 71-75 lead to the first group of five hundred consumers of heat energy with a high temperature level of 80-302С, such as, firstly, radiators, secondly, Ge machines, for example, dishwashers and washing machines, dryers, etc. .p., thirdly and fourthly, storage water heaters and, fifthly, a heating system with a heated floor. Feed lines 76-79 lead to yuyu

Зз5 of the second group of thermal energy consumers with a low temperature level of 25-202С, for example, pipes in internal dry walls, in internal floors, in external walls and in two different accumulators of the Earth's heat. In addition, the third Z and fourth 4 distribution devices are provided. The return line 80 of the heat pump 8 is connected to the single input of the distribution device Z. The output lines 31-34 of the distribution device Z lead to the supply lines 71-74 of heat energy consumers with a high temperature level. The line 90 coming from the cooling energy consumer 9 is connected to the single input of the distribution device 4. The output lines 41-44 of the distribution device 4 are connected to the supply lines 77-79 of heat energy consumers with a low energy level. Next, two collector devices 5, 6 are provided. The input lines 51-54 of the collector device 5 are connected to the output lines 12-16 and 22-26 of the distribution devices 1, 2, leading to the supply lines 72-75 for heat consumers with high temperature The single output line 50 of the collector device 5 leads to the heat pump 8. The input lines 61-65 of the collector device are connected to the lines 16-19 of the distribution device 1, which leads to the supply lines 76-79 of consumers with a low temperature level, and to the lines 26-29 sl of the distribution device 2. The single output line 60 leads to the heat pump 8.

The heat pump 8 contains an evaporator 81, the outlet of which is connected to a compressor 83 through a line 82, and

Ge») condenser 84. Line 60, leading from collector device b to heat pump 8, contains a mixing device 85, which is connected to a three-line valve 87 via line 86. In line 88, there is a CO pump 89. Cooling energy consumer 9 contains a coil 91 , connected to the mixer device 85 and the three-line (Che) valve 87. In the leading from the three-line valve 87 to the distribution device 4 of the line 90 is the mixing valve 45, to which the leads back to the solar collectors A, B of the line 10a, 20a are connected.

Instead of the solar collector B, an ambient heat collector or an Earth heat accumulator can also be provided. There are 30 pumps in many lines.

The installation works as follows. c On the output line 10 of the solar collector A, the heated coolant is fed to the distribution device 1.

Depending on the temperature of this heat carrier, it is supplied through one of the output lines 11-19 to the heat energy consumer that is designed for the temperature available. If, for example, the solar collector A gives a coolant with a temperature of about 802C, then it is supplied through the distribution device 1 on line 11 to the supply line 71 for the consumer with the highest temperature level, for example, to a group of radiators. If, on the contrary, the solar collector A gives a coolant with a temperature of 302C, then it is supplied through the distribution device 1 along line 15 to the supply line 75 for the heating system with heated floor. At an even lower temperature, the coolant is supplied through the distribution device 1 through one of the 65 lines 16-19" to one of the supply lines 76-79 to one of the consumers with a low temperature level.

Similarly, the heated coolant supplied by the solar collector B through the outlet line 20 to the distribution device 2 is supplied, depending on its temperature, through one of the lines 21-25 to one of the supply lines 71-75 to one of the heat consumers with a high temperature level and through to one of the lines 26-29" to one of the supply lines 76-79 to one of the heat consumers with a low temperature level.

Distribution devices 1, 2 thus ensure that the coolant reaches those consumers that are designed for the temperature of this coolant. Since the return lines 7Та-7У9а of thermal energy consumers are connected to the supply lines of the next consumer, respectively, the coolant can be passed through other consumers depending on the heat engineering requirements, due to which the thermal energy contained in it is given to these other consumers. 70 If there is a need to introduce additional thermal energy into the installation, then along one of the lines 51-54, coming from both collectors A, B or from consumers with a high temperature level, the coolant is supplied through the collector device 5 and through the line leading to the heat pump 8 line 50 to the condenser 84 of the heat pump 8. In the condenser 84, the temperature of the coolant rises to the value required by one of the heat consumers with a high temperature level. With the help of a distribution device from one of the lines 31-34 to one of the /5 supply lines 71-74 for consumers with a high temperature level, the heat pump 8 delivers coolant with a temperature of 80-302С. Since a coolant with a high temperature level is supplied to the heat pump 8 through the collector device 5, its temperature can be increased by the heat pump 8 to the required high values. With the help of the collector device b, the heat carrier coming from the solar collectors A, B or from one of the consumers of heat from the mountains with a low temperature level is supplied to the evaporator of the heat pump 8 through the distribution devices 1, 2. Thanks to the choice made by the collector device b, according to which the coolant coming from the collectors or consumers is supplied to the heat pump 8, it is possible to take into account the fact that the efficiency of the heat pump 8 increases when a coolant with a relatively precisely set temperature value is supplied to it, for example , 302S. The cooled heat carrier given by the evaporator 81 of the heat pump 8 is supplied through the three-line valve 87 to the coil 91 of the cooling energy consumer 9.

The heat carrier in the return line of the refrigerating unit U can be mixed through the three-line valve 87 to the heat carrier in the supply line. In addition, the coolant in the return line of the refrigerating unit U can be mixed through the mixing valve 85 with the coolant in the feed line for the evaporator 81. Due to this, the temperature of the coolant supplied to the consumer of refrigeration energy 9 can be regulated. The return line of the consumer of refrigeration energy U through the valve mixer 85 and line 90 is connected to the input of the distribution FdF) device 4, from where the coolant enters one of the lines 41-44 to the supply lines 77-79, leading to one of the heat consumers with a low temperature level. Since the return lines 75a-7ua are connected through the collector device 6 and through its output line 60 to the mixing valve 85, a coolant with a low temperature can be sent from one of the low-temperature heat consumers to the refrigeration unit. i am

Temperature sensors are installed in individual lines, measuring the temperature of the coolant located in all these lines. The outputs of the temperature sensors are connected to the central control unit, which enters all the data required for the operation of the installation, for example, external temperatures, the heat demand of individual consumers, etc. With the help of the control program, distribution and collector devices are controlled in such a way that, depending on the supply of thermal energy and the need for it, optimal use of the installation is ensured. Since coolant with very low temperatures is returned to solar collectors A and B respectively, their efficiency increases. From the solar collectors A, B, the heated coolant is supplied to those consumers who must be loaded with the corresponding temperature. "» Due to the sequential inclusion of thermal energy consumers with different temperatures and levels, the thermal energy contained in the coolant is fully used. Excessive thermal energy accumulates in one of the thermal accumulators, and in case of insufficient supply of thermal energy by the collectors, ambient heat is taken from these accumulators.

If the need for thermal energy cannot be covered by collectors of ambient heat and heat accumulators, the heat pump 8 is additionally turned on. Using the collector device 5 to

Ge") of the heat pump 8 is supplied with a heat carrier with a high temperature value, due to which the heat pump 8 raises the temperature of the heat carrier to the required high temperature. Using the collector device 6 to

Me heat pump 8 supplies a coolant with such temperature values that ensure its high efficiency.

Thermal energy accumulated in the refrigeration unit is returned to the unit. If the collectors A, B give cooling energy, then it can be directed through the distribution 1, 2 and collector 6 devices, as well as the mixing valve 85 to the cooling energy consumer 9.

Due to this, the installation ensures optimal use of the coolant and timely and high-quality supply of thermal energy to consumers.

Claims (12)

The formula of the invention 1. Installation for providing consumers with thermal energy, which contains the output line of the coolant heated in at least one heat source (A, B), and the output line is connected to the input of at least one distribution device (1, 2) corresponding to it, made with many outputs, to which are connected b5 supply lines (71-79) to consumers of thermal energy with different temperature levels, while the distribution device (1, 2) is made with the possibility of choosing one of the consumers to supply the heated coolant. 2. Installation according to claim 1, which is characterized by the fact that heat energy consumers with different temperature levels are connected in series to ensure consistent washing with the coolant. 3. Installation according to claim 1 or according to claim 2, which differs in that at least one heat source is made in the form of a solar collector (A, B). 4. The installation according to any of claims 1-3, which is characterized by the fact that at least one heat source is made in the form of an environmental heat collector or an accumulator of the Earth's heat, etc. 5. Installation according to claim 3, which differs in that it contains at least two solar collectors (A, B), oriented 7/0 V in different directions. 6. Installation according to any of claims 1-5, which is characterized by the fact that at least one heat source is made in the form of a heat pump (8). 7. Installation according to any of claims 1-6, which differs in that the return lines (Uba - 79a) of consumers with a low temperature level are connected to the inputs of the collector device (6), made with a single output 7/5 Line (60) , which is connected to the input of the heat pump (8), and with the help of the collector device (6), the consumer whose return line is connected to the heat pump (8) is selected. 8. Installation according to any of claims 5, 6, which is characterized by the fact that the return lines of consumers of thermal energy with a low temperature level are connected through the collector device (6) to the evaporator (81) of the heat pump (8), and the return lines of consumers of thermal energy energy with a high temperature level - Through the additional collector device (5) to the condenser (84) of the heat pump (8). 9. Installation according to any one of claims 1-8, which is characterized by the fact that the output of the heat pump (8) is connected to the input of an additional distribution device (3), made with many outputs leading to consumers with a high temperature level, and with the help of this additional distribution device (3), one of the consumers is selected, to which the coolant is supplied from the heat pump (8). 10. The installation according to claim 9, which differs in that the heat pump (8) is made with an evaporator (81), like Tenerpi. With a compressor (83) and a condenser (84), and a cooling energy consumer (9) is connected to the evaporator (81). 11. Installation according to claim 10, which differs in that the return line (90) of the consumer (9) of cooling energy is connected to the input of an additional distribution device (4), to the outputs of which consumers with a low temperature level are connected, and with the help of this additional distribution device (4) select one of the consumers to which the coolant heated in the consumer (9) of cooling energy is supplied. 12. Installation according to claim 11, which differs in that the return line of the consumer (9) of the cooling energy is connected to the mixing valve (85), to which the lines leading to the heat collectors (A, B) and He to the evaporator (81) are connected ) of the heat pump (8). IF) p - and? име) 1 (o) (ee) iChe) 60 b5