RU2609266C2 - Heat and cold supply system - Google Patents

Abstract

FIELD: energy.

SUBSTANCE: invention relates to heat engineering, namely, to central heat and cold supply. Heat and cold supply system, including an absorption refrigerating machine (ABRM), evaporator of which is connected to the delivery and return pipeline of cold supply, and a condenser and absorber of the ABRM are located on the cold-water pipeline and additional cooling circuit with a cooling tower. Cold accumulator is connected to the delivery and return pipeline of cold supply.

EFFECT: uninterrupted providing the consumer with required amount of heat for ventilation and heating in the cold season, for all-year DHW and with required amount of cold of the corresponding temperature level in any season providing the control of the cold supply level.

1 cl, 1 dwg

Description

The invention relates to the field of power engineering, in particular to district heating and cooling.

The following heat supply schemes are known: a two-stage scheme for connecting hot water water heaters for residential and public buildings and residential districts with a dependent connection of heating systems in a central heating center (TSC) and an individual heating station (ITP) and a two-stage scheme for connecting hot water heaters for residential and public buildings and residential districts with independent connection of heating systems in the central heating and heat and power engineering units (Code of Design and Construction Rules 41-101-95 “Designing of heating units”), which are schemes of a heating unit that provides the consumer with a year-round load on hot water supply (DHW) and a seasonal load on heating. The disadvantages of the above schemes are the lack of the possibility of a centralized supply of cold to consumers and the lack of heat and cold storage systems. Thus, the task of providing consumers with both heat and cold (primarily for ventilation and air conditioning of residential, public and industrial premises) is known and relevant.

A solution to this problem is known (see patent for the invention RU 2518777, publ. 2014), combining the efficient use of energy resources through the use of storage systems with minimizing the cost of electricity for producing cold due to the use of an absorption refrigeration machine (ABCM) for producing cold. In a power plant from RU 2518777, heat energy accumulators and ABHM are connected to district heating networks and represent advanced equipment of a heating center. The installation known from RU 2518777 is unnecessarily complicated and ineffective for use in conjunction with district heating networks due to the excessive amount of heat exchange equipment and heat storage means, with insufficient and as a result of ineffective use of the ABCM together with the equipment of the heating center.

In turn, the proposed invention, which is a heat and cold supply system, will overcome existing shortcomings and ensure uninterrupted supply of the consumer with the required amount of heat for ventilation and heating during the cold season, for the needs of hot water supply year-round and the required amount of cold, corresponding to the temperature level at any time of the year while ensuring regulation of the level of refrigeration. The proposed heat and cold supply system involves the use of a two-stage scheme for connecting hot water water heaters, including a supply pipe, a return pipe, a cold water pipe, a hot water pipe, a hot water circulation pipe, and hot water heaters of the first and second stages. In the heat and cold supply system, a heat accumulator and an ABXM generator connected to a cold water pipeline with a condenser and an absorber ABXM and a cold accumulator connected to the ABXM evaporator are connected to the supply pipe.

The invention is illustrated in the drawing, which shows a two-stage diagram of the connection of hot water heaters, where the generator ABHM - 1; capacitor ABHM - 2; throttle valve - 3; regenerative heat exchanger ABHM - 4; throttling valve - 5 ABHM evaporator - 6; absorber ABHM - 7; ABHM circulation pump - 8; cooling tower - 9; circulation pump of the water circulation circuit ABHM - 10; three-way valve - 11; locking and regulating devices - 12, 13, 14, 15, 16; DHW water heater of the second stage - 17; locking and regulating devices - 18, 19, 20; locking and regulating devices - 21, 22, 23, 24, 25; DHW water heater of the first stage - 26; locking and regulating devices - 27, 28, 29, 30, 31, 32; heat storage circuit pump - 33; locking and regulating devices - 34, 35; heat accumulator - 36; locking and regulating device - 37; cold storage circuit pump - 38; heat storage circuit pump - 39; locking and regulating devices - 40, 41, 42; cold accumulator - 43; check valves - 44, 45, 46; locking and regulating devices - 47, 48; coolant circulation pump - 49; check valve - 50; supply pipeline - 51; return pipe - 52; cold water pipeline - 53; hot water pipeline - 54; DHW circulation pipeline - 55. In the diagram, different coolant circuits and equipment are indicated by different types of lines: the main one is heat exchange, control and pump equipment; thin - the internal circuit of the ABXM (absorbent / refrigerant); main dotted - DHW circuit; thin dashed - water circulation circuit ABHM; thickened - network water circuit; thin dashed with two strokes - coolant circuit.

The heating and cooling system works as follows.

From the heating network through the supply pipe 51, the heated fluid is supplied under pressure to the heating unit, the separation of its flow into components is carried out as follows: the shut-off and control device 35 controls the flow of the coolant through the heat accumulator 36 (the coolant, passing the heat accumulator, returns to the return pipe of the heating network 52); shut-off and regulating device 14 controls the flow of coolant going to the ventilation, heating, domestic hot water and cold production systems; shut-off and regulating device 15 controls the flow rate of the coolant going to the ventilation system (the coolant after the ventilation system returns to the return pipe of the heating network before the DHW heat exchanger of the first stage 26); locking and regulating device 16 controls the flow of coolant going to the heater of the second stage of the hot water supply 17.

Having passed the heat exchangers of the DHW system, the heating coolant returns to the return pipe of the heating network; the locking and regulating device 22 controls the flow rate of the coolant going to the ABXM generator (after passing through the ABXM generator, the heating coolant either returns to the return pipe of the heating network before the first-stage hot water heater, either enters the consumer heat supply system, or part of the flow returns to the return pipe, and part of the flow enters the heating system, the flow rate of the heating medium returning to the return pipe after the ABXM generator is regulated by a shut-off and control device 21, and course of heating medium flowing into the heating system when the generator ABHM regulated locking and adjustment device 20); shut-off and regulating device 18 controls the flow rate of the coolant, going directly to the heating system of consumers (the consumer can be connected as a dependent or independent circuit). Having passed the building heating system, the heating coolant returns to the return pipe of the heating network.

The heating fluid after the heating system, the ABXM generator, the ventilation system and the second-stage hot water heater is mixed in the return pipe and enters the first-stage hot water heater 26, the flow of the heating coolant through the first-stage hot water heater is controlled by a shut-off-control device 24. The ABHM 1 generator can work as sequentially and in parallel with the heating system. The flow of cold water going to the needs of hot water supply is distributed as follows: the flow of cold water going to the heater of the first stage of hot water supply is regulated by a shut-off and control device 25; cold water (all or part of the flow rate) can be preheated in the ABHM 2 condenser and the ABXM absorber 7. The connection of the condenser 2 and the absorber 7 with the cold water pipeline can improve the ABCHM operational characteristics - reduce the condensation and absorption temperatures, as well as reduce the heat load hot water supply by pre-heating cold water in a condenser and absorber.

The flow of cold water through the condenser ABHM is regulated by a locking and regulating device 19; if cold water needs to be heated only in the ABHM condenser, then the shut-off and control devices 27 and 47 are closed and 19 and 48 are open, then, having passed the ABHM condenser, cold water enters the DHW heater of the first stage; if cold water needs to be heated only in the ABXM absorber, then the shut-off and control devices 19 and 48 are closed, and 27 and 47 are open, then, having passed the ABXM absorber, cold water enters the DHW heater of the first stage; if cold water needs to be heated both in the ABXM condenser and in the ABXM absorber (in this case, the absorption temperature inside the ABXM is maintained above the condensation temperature), the shut-off and control devices 47 and 48 are closed, and 19 and 27 are open, then, after passing through the ABXM condenser and absorber ABHM, cold water enters the DHW heater of the first stage; after the domestic hot water heater of the first stage, cold water is mixed with the water of the domestic hot water circulation system from the domestic hot water circulation pipe 55 and enters the domestic hot water heater of the second stage 17 and then through the domestic hot water pipe 54 to the domestic hot water consumer.

The water circulation system for removing heat from the ABHM works as follows: if the flow of cold water going to the needs of the domestic hot water supply is not enough to remove heat from the ABHM condenser and the ABXM absorber, it is necessary to turn on the water circulation circuit; after cooling tower 9, chilled water is supplied to the ABXM condenser and ABXM absorber, the chilled water is circulated by a circulation pump 10, a three-way valve 11 is used to separate the flow of recycled water into the flow going to the ABXM condenser and the flow going to the ABXM absorber; locking and regulating device 13 is used to control the flow of circulating water through the condenser ABHM. The locking and regulating device 30 is used to control the flow of recycled water through the absorber ABHM; shut-off and regulating devices 12, 29 and 31 are used to switch circulating water movement patterns, if shut-off and controlling devices 12 and 31 are closed and shut-off and controlling device 29 is open, the circulating water is sequentially moved through the ABXM condenser and the ABXM absorber. If the shut-off and control devices 12 and 31 are open, and the shut-off and control device 29 is closed, independent (parallel) movement of the circulating water through the ABXM condenser and the ABXM absorber occurs.

The ABCM scheme is inscribed in the technological scheme as follows. In the generator 1, due to the heat of the heating coolant, the refrigerant is evaporated (the type of refrigerant depends on the type of ABXM, and also depending on the type of ABXM, a distillation column and a reflux condenser can be built into the generator). The refrigerant evaporated in the generator enters the ABHM 2 condenser, where it condenses, giving off heat to either cold water going to the needs of hot water supply or water circulating water, it is also possible that part of the condensation heat is removed by the water circulation cycle, and part cold water going to the needs of hot water supply. A weak (with respect to the refrigerant) solution from the ABXM generator is throttled through valve 5 to the ABXM absorber, after passing through the heat exchanger of solutions 4, where it transfers heat to the strong solution coming from the ABXM absorber to the ABXM generator; after condensation in the ABXM condenser, the refrigerant is throttled by valve 3 to the ABXM evaporator 6. In the evaporator, a pressure is maintained at which the evaporation temperature corresponds to the required level of the resulting cold, taking into account the final temperature difference between the refrigerant and the refrigerant in the ABXM evaporator; the refrigerant vapor from the ABXM evaporator enters the ABXM 7 absorber, where it is absorbed by a weak (by refrigerant) solution. As a result of the absorption of refrigerant vapors with a weak solution, a strong solution is formed, the heat of absorption is given either to cold water that goes to the needs of hot water or to circulating water, it is also possible that part of the heat of condensation is removed by the water cycle, and part of cold water that goes to the needs of hot water. A strong solution from the ABXM absorber is fed back by the circulation pump 8 to the ABXM generator, after having previously passed the heat exchanger of the solutions.

The cold accumulation scheme works as follows: the locking and regulating device 28 regulates the flow of the coolant through the cold consumer and the cold storage system. During hours when the consumer’s cold consumption is lower than the capacity of the ABCM, the cold accumulator 43 is charged, the shut-off and control devices 39 and 40 are closed, and the shut-off and control devices 41 and 42 are open, so the coolant partially goes to the cold consumer, and partially to the cold accumulator (or only to the cold accumulator). The locking and regulating device 41 controls the flow of coolant through the cold accumulator during charging. In hours when the amount of consumer cold consumption is higher than the performance of the ABXM, a cold battery is discharged. The locking and regulating devices 39, 40 and 42 are open, and the locking and regulating device 41 is closed, with the help of the pump 38, the coolant is pumped from the return pipe from the cold consumer through the cold accumulator in the opposite direction (the battery is discharging). If it is necessary to disconnect the cold accumulator from the system, shut-off and regulating devices 41 and 42 are closed. The cold accumulator 43 allows to reduce the calculated cooling capacity of the ABCM, as well as to “smooth out” the variable cooling schedule and ensure the operation of the ABCM without sudden changes, which in turn leads to more stable heat consumption of the entire circuit in time.

The heat storage system operates as follows. At hours when the amount of heat energy consumed by the ABXM generator is lower than the flow rate of the supply pipe can be ensured, or at hours when the ABXM is not working, due to the lack of cold load, the heat accumulator 36 is charged, shut-off and control devices 32 and 37 are closed and the locking and regulating devices 34 and 35 are open. Thus, the heating coolant is partially directed to the ABXM generator, and partially to the heat accumulator. The locking and regulating device 35 controls the flow of heat carrier through the heat accumulator during charging. In hours when the amount of heat energy consumed by the ABHM generator is higher than can provide the throughput of the supply pipe, the heat accumulator is discharged. The locking and regulating devices 32, 35 and 37 are open, and the locking and regulating device 34 is closed. Using the pump 33, the heating coolant is pumped from the return pipe of the heating network through the heat accumulator in the opposite direction (the battery is discharged). To prevent the backflow of water after the pumps, check valves 44, 45, 46, 50 are provided. the heat accumulator 36 is connected in parallel to the heating network, and not in series, it becomes possible to exclude it from the system if necessary. The same connection of the heat accumulator 36 allows, if necessary, to increase the consumption of hot water at the entrance to the system due to the simultaneous consumption of hot network water from the supply pipe of the heating network and the heat accumulator when the pump 33 is turned on (i.e., creating a recirculation loop through a charged battery).

Claims (2)

1. The heat and cold supply system, including sections of the supply and return pipelines of the heating network, to which the heat exchange equipment of hot water supply, a heat accumulator, an absorption refrigeration machine (ABHM) are connected, the evaporator of which is connected to a supply and return cooling pipe, characterized in that the condenser and absorber ABHM located on the cold water pipeline and an additional cooling circuit with a cooling tower. 2. The heat and cold supply system according to claim 1, characterized in that a cold accumulator is connected to the supply and return cooling pipe.

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