RU2232351C2 - Automatic heat-supply station - Google Patents

Abstract

FIELD: heat and power engineering, namely closed heat supply systems with subordinate circuit for connecting heating system.

SUBSTANCE: automatic heat supply station of heating system includes supply pipeline of heat power network in which flow rate controller is used; supply pipeline of heating system connected with return pipeline of heating system by means of bridge having successively connected mixing pump and mixing regulator; water heater of hot water supply system connected between supply and return pipelines of heat power network. Control inlet of mixing regulator is connected with outlet of heating regulator whose inlets are connected with pickups for measuring temperature of heating system and environment. Three-way Valve is used as mixing regulator. Inlet of said valve is connected with outlet of mixing pump, its first outlet is connected with supply pipeline of heating system, its second outlet is connected with return pipeline of heat power network. Control inlet of flow rate controller is connected through pressure drop pickup respectively with supply and return pipelines of heating system. Automatic heat supply station of heating system also includes supply pipeline of heat power network with flow rate controller mounted in said pipeline, supply pipeline of heating system provided with elevator, mixing pump. Adding inlet of elevator is connected with return pipeline of heating system through first non-return valve and with return pipeline of heat power network through second non-return valve in direction opposite relative to direction of connecting first non-return valve. Mixing pump through filter is connected with return pipeline and through three-way valve used as mixing regulator it is connected with outlets of first and second non-return valves respectively by first and second outlets of three-way valve. Control inlet of three-way valve is connected with outlet of heating regulator whose inlets are connected with temperature pickups. Control inlet of flow rate controller is connected with outlet of pressure drop pickup in supply and return pipelines of heating system. Method of automatic control of parameters of heating system comprises steps of measuring fluctuation of above mentioned parameters relative to preset values; adding water from return pipeline to supply pipeline by means of mixing pump through filter successively connected with mixing pump. At least two mixing pumps with filters are used. Mixing pumps are alternatively stopped for washing out filter connected successively with non-operating pump by creating countercurrent flow of water with use of operating pump through non-operating pump.

EFFECT: enhanced efficiency of station in condition of insufficient water pressure at inlet of heat power network and deficient heat supply, improved operational capability and reliability of station.

6 cl, 6 dwg

Description

The invention relates to a power system and is intended for use in closed heat supply systems with a dependent heating system connection scheme.

Known automated heat point (ATP) of the heating system and hot water supply, including the supply and return pipelines, on which a flow controller is connected, connected to an electronic heating controller, a circulation pump, filters, sumps, temperature sensors, as well as a check valve on the jumper between the mentioned pipelines [1]. The disadvantage of this ATP is poor performance with a small available head at the input of the heating network, reduced reliability associated with increased thermal overloads of the pump, as well as the inability to stabilize the flow in the heating system.

These disadvantages are partially eliminated in the ATP patent [2], which is the prototype of the claimed invention. This ATP contains a supply pipe to the heating network with a flow controller installed in it, a supply pipe to the heating system connected to a return pipe of the heating system by a jumper including a mixing pump and a mixing controller connected in series, the control input connected to the output of the heating controller, the inputs of which are connected to temperature sensors in the heating system and the environment, a hot water heater connected between the supply and return pipelines floor network, as well as a mixing device (elevator), included in the supply pipe of the heating system and connected by a jumper to the return pipe.

The disadvantage of the ATP prototype is poor performance with a small available head at the input of the heating network, low reliability due to emergency modes of operation of the mixing pump in the extreme temperature conditions of the ATP. In addition, the disadvantage is the low operational ability due to the need for periodic shutdown of the ATP for the filter of the mixing pump.

The objectives of the invention are to increase the efficiency of the ATP with insufficient available pressure at the input of the heating network and a deficient heat supply, increase operational capacity and reliability.

These tasks are solved as follows.

In ATP of a heating system and hot water supply, containing a supply pipe of a heating network with a flow regulator installed in it, a supply pipe of a heating system connected to a return pipe of the heating system by a jumper including a mixing pump and a mixing controller connected in series to a temperature sensor in the system heating and the environment, as well as a hot water heater, connected between the supply and return pipelines of the heat Thus, a three-way valve is introduced as a mixing controller, the input of which is connected to the output of the mixing pump, the first output is connected to the supply pipe of the heating system, and the second output is connected to the return pipe of the heating network, and the control input of the flow controller is connected to the output of the differential pressure sensor in the supply and return piping of the heating system.

An ATP variant is proposed, in which the hot water supply system heater is made up of series-connected units of the first and second stage, the second output of a three-way valve being connected to the return pipe of the heating system through the said second-stage unit.

In addition, an ATP variant is proposed in which the mixing pump is connected to the return pipe of the heating system through a series-connected filter and a check valve, an additional mixing pump is introduced with a filter and a check valve connected in series with it, the mixing pump and the additional mixing pump through the corresponding filters and check valves are connected in parallel, and the dirt traps of the above filters are connected through check valves to the inlet of the subscriber sump included in the return pipe heat conductive network.

An independent ATP variant is proposed, comprising a supply pipe to the heating network with a flow regulator installed in it, a supply pipe to the heating system with an elevator included in it, a mixing pump, while the mixing inlet of the elevator is connected to the return pipe of the heating system through the first non-return valve and to the return thermal pipe network through the second non-return valve in the direction opposite to the first non-return valve, the mixing pump through the filter is connected to the return pipe, and through a three-way a valve used as a mixing controller is connected to the outputs of the first and second check valves, respectively, the first and second outputs of the three-way valve.

A variant of this ATP is proposed, in which the control input of the flow controller is connected to the output of the first and second impulse tubes, respectively connected at the outlet of the elevator to the supply pipe of the heating system and at the output of the return pipe of the heating system.

A method is also proposed for automatically controlling the parameters of the heating system, in which the washing of the filters of the mixing pumps is performed without stopping the operation of the ATP. This method consists in measuring the departure of the mentioned parameters relative to the set ones, mixing the water from the return pipe into the direct pipe using a mixing pump through a filter with a dirt trap connected in series with the mixing pump, using at least two mixing pumps with the mentioned filters, connected in parallel with each other, and the mixing pumps alternately turn off and flush the filter, connected in series with the pump turned off, by means of a counterflow of water, created by the pumps on, through the pump off.

The operation of the claimed ATP and the essence of the method for automatically controlling the parameters of the heating system is explained below using Fig.1-6.

Figure 1 shows the ATP of a heating system and hot water supply, comprising a supply 1 and a return 2 pipelines of a heating network (TS), a supply 3 and a return 4 pipelines of a heating system (CO) with a flow regulator 5 installed in the supply pipe 1, a jumper between the supply 3 and the return 4 pipelines of the heating system, including a mixing pump 6 connected in series and a mixing controller 7, a control input connected to the output of the heating controller 8, the inputs of which are connected to temperature sensors in the heating system I and the environment 9, 10 and 11. As a mixing controller 7, a three-way valve is introduced, the input of which is connected to the output of the mixing pump 6, the first output (A) is connected to the supply pipe of the heating system 3, and the second output (B) is connected to the return pipeline heating network 2, and the control input of the flow controller 5 is connected via a differential pressure sensor 12, respectively, with the supply 3 and return 4 piping of the heating system. The water heater of the hot water supply system (DHW) 13 is connected between the supply 1 and return 2 pipelines of the heating network.

In addition, in Fig. 1 and further, the traditional designations indicate valves and equipment that do not affect the description of the operation of the ATP in this application (ZA - stop valves used only when repairing the ATP and being in the open state during the operation of the ATP, KR - the control valve for hot water supply )

Figure 2 presents the variant of the ATP, in which the water heater of the hot water supply system 13 is made of series-connected blocks of the first 14 and second 15 stages, the second output of the three-way valve connected to the return pipe of the heating system through the said block of the second stage.

Figure 3 shows the variant of the ATP, in which the mixing pump 6 is connected to the return pipe 4 of the heating system through a series-connected filter 16 and a check valve 17, an additional mixing pump 18 is introduced with the filter 19 and the check valve 20 connected in series with it, and the mixing pump and an additional mixing pump through the corresponding filters and check valves are connected in parallel, and the dirt traps of the filters 16 and 19 are connected through the check valves 21 and 22 to the input of the subscriber sump 23, included a return pipe 2 of the heat network.

Figure 4 presents a variant of the ATP of a heating system, comprising a supply 1 and return 2 pipelines of a heating network with a flow regulator 5 installed in a supply pipe 1, a supply 3 and a return 4 pipelines of a heating system with an input 25 and an output 26 included in the supply pipe 3 of the elevator 24 The mixing inlet of the elevator 27 is connected to the return pipe 4 of the heating system through the first non-return valve 28 and to the return pipe of the heating network 2 through the second non-return valve 29 in the direction opposite to the first non-return valve wherein the mixing pump 6 through the filter 16 is connected to the return pipe 4, and through the first (A) and second (B) outputs of the mixing controller (three-way valve) 7 is connected to the outputs of the first 28 and second 29 check valves, respectively, by the outputs A and B of the three-way valve 7, the control input of which is connected to the output of the heating controller 8, the inputs of the latter are connected by sensors of ambient temperature and CO. The control input of the flow regulator 5 is connected to the output of the differential pressure sensor in the forward and return pipelines СО 12.

Figure 5 presents the variant of the ATP, in which the differential pressure sensor 12 is made in the form of the first 30 and second 31 impulse tubes, respectively connected at the output 25 of the elevator 24 in the supply pipe of the heating system 3 and at the output of the return pipe of the heating system 4.

Figure 6 presents one of the possible variants of the ATP, which implements a method for automatically controlling the parameters of the heating system, which includes automatic washing of the filters of the mixing pumps without shutting them down and maintaining the health of the ATP as a whole. This ATP is based on the ATP in Fig.5. It provides an additional mixing pump 18 with a filter 19 and a non-return valve 20 connected in series with it, a non-return valve 17 in the pump circuit 6, while the mixing pump circuits are connected in parallel. Filters 16 and 19 through the check valves 21 and 22 are connected to the input of the subscriber sump 23 included in the return pipe of the heating network 2.

ATP in figure 1 works as follows.

The change in temperature of the coolant entering the CO occurs due to a change in the position of the three-way valve 7, which changes with the mixing pump 6 the amount of admixture of the coolant returning from CO.

With an increase in the ambient temperature, the required decrease in the temperature of the coolant in CO occurs as follows. The three-way valve 7, upon receipt of a corresponding signal from the heating controller 8, to which incoming signals are received from the sensors of the outdoor temperature 11, the temperature of the supply pipe 3 of CO 9 and the return pipe 4 of CO 10, increases the flow area of the outlet (A) by mixing into the supply pipe 3 TS and reduces the bore (B) in the return pipe of the TS. There is an increase in the mixture and, accordingly, the flow rate of the coolant in CO, which causes an increase in the pressure difference in the supply 3 and return 4 pipelines of CO. In this case, the differential pressure sensor 12 causes a change in the position of the flow regulator 5, which leads to a decrease in the flow area of the valve of the regulator 5 and thereby reduces the flow rate of the coolant from the supply pipe 1. The flow rate of the coolant in CO returns to its previous (set) value. Thus, the temperature decreases due to a change in the mixing coefficient of the coolant from direct 1 and return 4 pipelines.

With decreasing ambient temperature, the required temperature increase in CO occurs in a similar way.

The operation of the water heater 13, included in a single-stage scheme, occurs in a standard manner. The temperature of the coolant entering the domestic hot water system is regulated by changing the flow rate of the coolant in the primary circuit of the water heater.

ATP in figure 2 works similarly to the ATP shown in figure 1, while the water heater is turned on in a two-stage scheme.

In the ATP in FIG. 3, two mixing pump circuits are used, connected in parallel, which, in addition to increasing reliability, allows automatic alternating washing of filters 16 and 19 periodically. Washing is performed as follows. From time to time, the pumps are alternately stopped and their filters rinsed in countercurrent from the running pump. Check valves are installed upstream of the pumps. During flushing, the check valve of the stopped pump directs the flow of coolant through the filter in the opposite direction to the subscriber sump 23 installed in the return pipe TC 2.

An independent version of the ATP, presented in figure 4, works as follows.

In this scheme, the elevator 24 serves as a backup pump. The temperature change of the coolant entering the CO occurs due to a change in the position of the three-way valve 7, which changes with the mixing pump 6 the amount of the mixture of the coolant returning from the CO and arrives at the mixing inlet 27 of the elevator 24.

With an increase in the ambient temperature, the required decrease in the temperature of the coolant in CO occurs as follows. The three-way valve 7, upon receipt of the corresponding signal from the heating controller 8, to which the incoming signals from the sensors of the outdoor temperature, the supply and return piping temperature sensors CO receive, increases the flow cross section of the outlet (A) and, therefore, the coolant is mixed through the mixing inlet 27 of the elevator 24 and then it enters through the outlet 26 into the supply pipe 3 WITH; at the same time, it reduces the flow cross section of the outlet (B) to the return pipe of TS 2. There is an increase in the flow rate of the coolant in CO, which causes an increase in the pressure difference in the supply 3 and return 4 pipelines of CO. In this case, the differential pressure sensor 12 causes a change in the position of the flow regulator 5, which leads to a decrease in the flow area of the valve of the regulator 5 and thereby reduces the flow rate of the coolant from the supply pipe 1. The flow rate of the coolant in CO returns to the set value. Thus, the temperature in CO decreases.

With decreasing ambient temperature, the process occurs in the opposite way.

In contrast to the ATP, shown in Fig.1-3, this ATP due to the use of the elevator remains operational when the power is turned off, causing the mixing pump to stop 6. The elevator works in normal mode, that is, the possibility of minimal regulation due to the constant elevator mixing ratio 24.

The ATP in Fig. 5 works similarly to the ATP shown in Fig. 4, while a direct-action regulator is used as a differential pressure regulator, in which the signals to the sensor 12 come from impulse tubes 30 and 31 located respectively in the supply 3 and return 4 pipelines With.

ATP in Fig.6. demonstrates a way to automatically control the parameters of CO, which implements flushing the pump filter while maintaining the health of the ATP. When one of the pumps is turned off - 6 or 19 - the working pump creates a counterflow through the filter in the circuit of the switched off pump - 13 or 20, respectively, while the dirt accumulated in the filters is washed through the check valves 23 or 24 into the subscriber sump 25. This automatic control method is implemented in variants of the ATP in figure 3 and can be implemented in a similar way in any ATP, where parallel circuits with mixing pumps are used.

Non-return valves 21 and 22 allow mutual counterflow between the pumps 13 and 20.

The following data were obtained on experimental samples made on the basis of the circuits shown in Figs. 1–6: the samples remain operational while decreasing the available pressure at the vehicle inlet to zero.

ATP in Fig.4-6 retain the ability to minimize adjustment and reduce the parameters of the coolant to the level of operational safety.

Sources of information

1. Utility model of the Russian Federation 19140, F 24 D 19/10 of 02.20.2001

2. RF patent 2031316, F 24 D 19/10 of 11.25.1991,

Claims (6)

1. An automated heating unit of a heating system, comprising a supply pipe of a heating network with a flow controller installed therein, a supply pipe of a heating system connected to a return pipe of a heating system by a jumper including a mixing pump and a mixing controller connected in series to a heating controller output, the inputs of which are connected to temperature sensors in the heating system and the environment, as well as a hot water heater, interconnected between the supply and return pipes of the heating network, characterized in that a three-way valve is introduced as a mixing controller, the input of which is connected to the output of the mixing pump, the first output is connected to the supply pipe of the heating system, and the second output is connected to the return pipe of the heating network, the input of the flow controller is connected through a differential pressure sensor, respectively, with the supply and return pipelines of the heating system. 2. The automated heating station according to claim 1, characterized in that the water heater of the hot water supply system is made up of series-connected units of the first and second stage, the second outlet of the three-way valve connected to the return pipe of the heating system through the said block of the second stage. 3. The automated heating station according to claim 1, characterized in that the mixing pump is connected to the return pipe of the heating system through a series-connected filter and a check valve, an additional mixing pump is introduced with a filter and a check valve connected in series with it, the mixing pump and an additional pump mixing through the corresponding filters and check valves are connected in parallel, and the above filters through check valves are connected to the input of the subscriber sump included in the return thermal conduit network. 4. An automated heating unit of the heating system, comprising a supply pipe to the heating network with a flow regulator installed in it, a supply pipe to the heating system with an elevator included in it, a mixing pump, characterized in that the mixing input of the elevator is connected to the return pipe of the heating system through a first non-return valve and with the return pipe of the heating network through the second check valve in the direction opposite to the first check valve, while the mixing pump through the filter is connected to piping, and through a three-way valve used as a mixing controller, connected to the outputs of the first and second check valves, respectively, the first and second outputs of the three-way valve, the control input of the three-way valve is connected to the output of the heating controller, the inputs of which are connected to temperature sensors, and the control input the flow controller is connected to the output of the differential pressure sensor in the supply and return pipes of the heating system. 5. The automated heating unit according to claim 4, characterized in that the differential pressure sensor is made with first and second impulse tubes connected respectively at the outlet of the elevator to the supply pipe of the heating system and at the output of the return pipe of the heating system. 6. A method of automatically controlling the parameters of the heating system, which consists in measuring the departure of the above-mentioned parameters relative to the set ones, mixing the water from the return pipe into the direct pipe using a mixing pump through a filter connected in series with the mixing pump, characterized in that at least two mixing pumps with the mentioned filters, connected in parallel with each other, and the mixing pumps are alternately turned off and flush the filter, connected in series with the pump turned off, through the counterflow of water created by the pumps on, through the pump off.

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