RU2216693C2 - Device for heating in standby mode of operation - Google Patents

Abstract

FIELD: heat generators, stand-alone building heating systems, particularly for automatic heating systems using liquid or solid fuel. SUBSTANCE: device has heating channel, heater connected in by-pass with heating channel. By-pass inlet and outlet are made as connection pipes. Connection pipe area is less than channel area. Outlet connection pipe end is coaxial with channel and disposed below inlet connection pipe in flow direction. Inlet connection pipe axis is offset relative channel axis. EFFECT: providing of simultaneously operating in main mode with forced circulation and standby mode with gravity circulation; energy-saving; increased efficiency of heating system. 2 cl, 4 dwg

Description

 The invention relates to heating systems for individual buildings with a gas and electric heat generator and can be used in automated systems with heating solid and liquid fuels.

 Automated domestic gas heat generators are known [1, 2] for heating systems of individual buildings with gravity-type coolant circulation, for example AOGW [3], as well as with forced coolant circulation [4,5].

 The known heat generator [4], presented as an analogue, is equipped with a forced circulation of the coolant, installed in series with the heat generator in the hydraulic heating circuit. This allows you to increase by 15-20% the energy efficiency of the heating system.

 However, these devices require high-quality mains power. At present, in Russia it is impossible to provide electricity without interruptions. Therefore, for the normal functioning of well-known foreign-made devices [4] during the period of power outage, a backup power source, for example, a battery, a gas generator, etc. is required. The presence of a backup power supply significantly complicates operation and increases the initial cost of consumers by 2–3 times. At the same time, total interruptions in the supply of electricity do not exceed 5-8% of the calendar time of the heating period.

 The known heat generator [5] is a certain modernization [4], in which a check valve is located in the bypass in parallel with the pump installed in the heating channel in series with the heat generator in such a way that the pump turns off when the power is turned off, the pressure at its outlet decreases and the check valve opens under the action of the gravitational pressure drop created by the temperature difference between the cold and hot volumes of the coolant. This hydraulic arrangement of the pump in the heating channel and the non-return valve on the bypass allows you to play the role of an automatic switch of heating modes from forced circulation to free gravity in the absence of power supply, and when the power is turned on, return to the forced circulation mode. In this case, the functioning of the heating system does not depend on the mains power supply during the period of its shutdown.

 However, the bypass section with the non-return valve located in it has increased hydraulic resistance due to the presence of turns (local losses) in perpendicular directions. In this case, the heating system in gravitational mode occurs with an excessive decrease in hydraulic pressure and, as a result, leads to a decrease in the velocity of the coolant in the heating channel, a decrease in the rate of transient processes and a decrease in temperature in a heated room.

 These disadvantages are largely eliminated in the known device [6], adopted for the prototype, which contains a heating channel, a supercharger (pump) located on the bypass to the heating channel.

 In the scheme, when the pump is installed in the bypass, and the check valve is in the straight section of the heating channel, the hydraulic losses are much less. In the event of a power failure, the non-return valve opens in the direct heating channel with a larger cross section compared to the bypass pipeline and has a lower hydraulic resistance compared to the layout shown in [5].

 At the same time, it must be borne in mind that the check valve shuts off the gravity mode when closing, and if there is insufficient water treatment in the presence of an open heating system, the check valve can fail on one side - incomplete closure. Reducing the likelihood of such a failure will require more frequent prophylaxis, which is not always available to all users in order to prevent failure of the non-closing of the check valve. Such a failure leads to additional energy losses, disruption of the hydraulic circulation of various circuits of the heating system, unstable operation of the heating system together with the heat generator.

 On the other hand, the non-return valve, in the case of another type of failure - spring failure due to corrosion under heating conditions, will not open the channel at all when the pump stops. But in [5, 6] the gravitational regime is used during the survival of the system. The presence of negative external temperature, the prolonged absence of mains power and coolant circulation in the heating system are negative conditions when, due to freezing of the coolant, failure of pipelines and devices of the heating system, valves and an expensive heat generator can occur, leakage of the coolant into the premises of one or several floors, occurrence condensate on the building structure of the building and, as a result, financial losses. Types of failures "incomplete opening-closing" of the check valve or its "non-opening" reduce the reliability of the system.

 In addition, the non-return valve closes part of the pipeline section of the heating system, turning off one of the parallel channels for the flow of the coolant and leaving only one channel with the pump for the duct. This does not reduce the total hydraulic resistance of the channel along with the section where the parallel pipelines (bypass and channel) are located.

In addition, the closed part of the channel of the heating system into which the coolant is pumped under pressure is a dead end branch, in which conditions arise for the accumulation of various suspensions and mechanical admixtures of the coolant. Moreover, in time, the operation of the heating system in the forced circulation mode (accumulation of impurities in the dead end branch) is more than 90% of the time of the heating season. These conditions can lead to failures when opening the check valve, as the gravitational pressure drop is relatively small (~ several hundred Pa) compared with the pressure from the circulation pump (~ 10 ³ times more).

 In addition, closing the check valve leads to a loss of movement in the heating system and coolant flow rate due to the gravitational mode, which, combined with the flow rate due to the circulation flow, does not allow delivering more heat to the heating appliances and the heat consumer (person), and reduce the transition process and get a share of energy savings in the heating procedure.

 In addition, in the known devices there is a pronounced switching mode from the main to the standby heating mode, due to the presence of mechanical switching devices, and leading to a restructuring of the system and possible malfunctions.

 To eliminate the disadvantages of the known devices, a device for a standby heating mode is proposed, comprising a heating channel, a supercharger included in the bypass to the channel, characterized in that the bypass input and output are made in the form of pipes with a section smaller than the channel section, the output pipe section is located along the channel axis and below the inlet pipe downstream.

 In addition, in the device for the backup heating mode, the sections of the inlet and outlet nozzles are located coaxially with the channel section.

 In addition, in the device for the standby heating mode, the axis of the section of the inlet pipe is offset relative to the axis of the channel.

 In addition, in the device for standby heating mode, the cross section of the inlet pipe is located on the channel wall.

 The proposed device for the backup heating mode (drawing a, b, c, d) consists of a heating channel 1, pump 2 for forced circulation, located on the bypass 3 with outlet pipe 4 with section 5 and input pipe 6 with section 7. The arrows indicate the flow coolant. The device can be installed in the pressure and return channels of the heating system. Section 5 is aligned with the section of heating channel 1. The outlet pipe 4 together with channel 1 forms a jet pump in which pipe 4 is an active nozzle, section 8 of heating channel 1 is a chamber, from where a passive medium is sucked (coolant), section 9 of channel 1 is mixing and pressure recovery chamber to overcome the load, which is the resistance of a branched heating system, consisting of heating appliances, pipelines and fittings. The bypass inlet pipe 6, through which the coolant is supplied to the active nozzle (section 5) of the pipe 4, can be located in various design positions depending on the choice of its local hydraulic resistance in the heating channel.

 Thus, in such an arrangement, the device is a combination of actually two drivers, one of which is mechanical, driven by an electric motor and powered by the mains, the other is jet without moving parts, made according to the laws of construction of a water-to-water elevator (ejector) with a short or elongated mixing chamber with or without a diffuser. Section 9 can be made in the form of a mixing chamber with a diffuser, pipe 4 can be made in the form of a conical nozzle.

 The device (drawing a) is characterized in that section 5 of the pipe 4 of the bypass outlet 3 and section 7 of the pipe 6 are located on the same axis and are aligned with the section of the channel 1 of the heating system. In the standby (gravitational) mode of circulation of the coolant, there are two local hydraulic resistances in the sections of channel 1, where the inlet pipe 7 and the bypass outlet 4 are located 3. In the main mode (forced circulation), the most optimal arrangement of the bypass pipes 4 and 6 is 3.

 The device (drawing b) differs from the device according to the drawing, and pipelines 10, structurally integrated into one element, connecting the bypass 3 with pipes 4 and 6. Such a combination is more technologically advantageous, allows you to make one insert into the heating system channel and immediately place the input pipes and bypass output.

 The device (drawing c) is characterized by the fact that when operating in standby mode, the circulation of the coolant has a reduced local resistance in the section of the bypass inlet pipe 6, compared with the circuit in drawing a. When operating in the main circulation mode, the conditions for the absorption of the coolant into the bypass inlet 6 inlet with developed turbulent flow practically does not differ from the diagram in drawing a. The turbulent flow assumes a rectangular velocity diagram in channel 1 and the location of section 7 of pipe 6 of bypass input 3 can be considered indifferent.

 The device (drawing g) is characterized in that the cross section 7 of the bypass inlet 6 pipe 3 is located on the wall of the channel 1. In gravity mode, there is minimal local hydraulic resistance in this section of the channel. In the main circulation mode on the channel 1 section, where the pipe 4 is located, the flow going into the bypass pipeline 3 somewhat distorts the flow in the channel and the velocity diagram, creating local resistance by the interaction of two branching flows. However, the absence of a stationary body of the pipe 6 significantly reduces the hydraulic local resistance both in standby gravity mode and in the main mode.

 The device operates as follows.

 When the device is operating for a standby heating mode, hydraulic interaction of flows appears on the inlet bypass outlet and outlet. This is expressed in the form of a jet effect of ejection, which ensures automatic self-cleaning of the heating channel by using the transition from the combined operating mode (gravity plus forced circulation) to the purely gravity backup mode of the heating system during a power outage. Using the effect of self-cleaning in the proposed device and the absence of moving parts in the channel of the heating system significantly increases the reliability of the heating system.

 The proposed device is designed to work in conjunction with a coolant heater and heating system in a building, individual house, greenhouse, warehouse.

 The proposed device allows both primary and backup heating modes to function. When working in the main mode, i.e. when the power supply is not turned off, under the influence of a mechanical supercharger 2, which causes the coolant to flow through the bypass 3, the coolant from the heating system channel 1 through the nozzle 6 and 4 is pumped through the bypass and is again thrown back into the channel 1. The coolant jet emerging from section 5 of the nozzle 4 due to its inversion, it picks up the surrounding coolant layers, which have a lower flow velocity, and carries them further downstream, for example, through the return pipe (“return”) to the gas boiler tank. In section 9 of channel 1 at the location of section 5 of pipe 4, the hydraulic effect of ejection occurs at the moment of starting the circulation. Further, in static equilibrium, with equal flows in sections 9 and 10 of channel 1, there is a lower flow rate in section 8 compared to the flow rate in section 5 of bypass pipe 4. At section 9, the ejection effect will be manifested to a lesser extent. At this moment, the circulation of the coolant will only be adjusted due to the additional flow energy created by the electric circulation pump. A figurative comparison is how a hoop is rolled on a road with a stick.

 At the same time, circulation continues to work, as there is a flow load due to gravitational forces created by heating the heat carrier and the difference in the specific gravity of the upper and lower layers of the liquid in the heating system.

 When the power is turned off and the pump is stopped, the standby heating mode continues to work as in the presence of the main mode. In this case, circulation is carried out only by moving the temperature layers of the liquid by gravity. The coolant flow is carried out through channel 1 with a minimum local hydraulic resistance, which is created by pipes 4 and 6 (drawing a, b, c) or only pipe 4 (drawing d).

 In the proposed device to ensure the operation of the backup heating mode does not require devices with moving parts. The absence of moving parts in the heating channel 1, which passes the entire circulating flow, increases the reliability and service life compared to known devices.

 When the power is turned on, the main mode of operation in the circuits of the heating system resumes, provided by forced circulation from the pump. Simultaneously with the main mode, the standby mode continues to function.

Thus, the proposed device has the following advantages compared with the known:
- lack of moving parts
- lowered hydraulic resistance
- increased resource and reliability
- simultaneous operation of the main and standby modes allows to reduce the transition process time and increase energy saving
- there is no pronounced mode of switching from the primary to the backup
- the presence or absence of power supply does not lead to the disappearance of the circulation mode of heating, but only to its change in intensity.

Literature
1. Gas heating apparatus household AOGV-23, 2-1-U GOST 20219-74. Manual. Zhukovsky Engineering Production Association. G. Zhukovsky. 1988.

 2. N. L. Staskevich and others. Handbook of gas supply and gas use. -L .: Nedra, 1990, pp. 351-360.

 3. Interstate standard "Household gas heating apparatus with a water circuit." GOST 20219-93.

 4. Comparative characteristics of floor heating boilers of foreign production. Gas. Construction expert 34 (23) / 98 February.

 5. Electric boiler of the Rusnit type, models 212, 215, 221 and others. Passport and technical description. Ed. Ryazan, 2000.

 6. Gas heat generator. Certificate of the Russian Federation for utility model RU 11872 U1, class 6 F 24 H 9/20.

Claims (2)

 1. A device for backup heating mode, comprising a heating channel, a supercharger included in the bypass to the channel, characterized in that the bypass input and output are made in the form of pipes with a section smaller than the channel section, the output pipe section is located along the channel axis and below the input pipe downstream, while the axis of the inlet nozzle section is offset relative to the axis of the channel.  2. The device according to p. 1, characterized in that the cross section of the inlet pipe is located on the channel wall.