RU2195585C2 - Parallel multistage hot-water pump operating on principle of evaporation and condensation of water - Google Patents

Abstract

FIELD: mechanical engineering; thermal pumps. SUBSTANCE: steam formed in steam generating chamber under action of heat from combustion chamber passes through connecting steam pipe to provide discharging of water contained in pump chamber outside its limits in form of hot water through steam generating chamber, discharged water check valve, discharged water connecting channel, discharged water re-heat chambers, through outlet pipe and outlet discharge hole. At the same time, in pump chamber is fed to condensation chamber where it comes in contact with cold water which provides quick condensation of water and drop of pressure in chamber. Reduced pressure in condensation chamber provides suction of water through inlet suction hole, water suction channel and water suction check valve. Sucked-in water is fed to pump chamber through connecting suction pipe. EFFECT: improved heating, increased capacity. 6 dwg

Description

 The invention relates to thermal pumps, and more particularly to parallel multi-stage thermal pumps using evaporation and condensation of water.

 The thermal pump according to the invention does not belong to the type of pumps that pump hot water by means of a medium-speed steam engine, or to circulation pumps, or to pumps that draw in cold water supplied by another pump, but belongs to parallel multi-stage hot water thermal pumps, in which the pumping process includes the stages of heat generation from fuel combustion, the evaporation of water under the influence of this heat and the subsequent condensation of the evaporated water.

 The present invention provides more efficient heating and increased productivity. The present invention is a device for pumping large volumes of hot water, and more specifically, less than half or a quarter of the volume of a conventional hot water boiler.

The aforementioned conventional hot water boiler (or hot water generation device) necessarily requires a circulation pump that circulates hot water and a water pump that supplies cold water, while the boiler does not provide efficient combustion of fuel when there is a lot of fuel, as a result which does not solve the problem of soot formation during combustion, and does not provide reduction of the formation of poisonous gases (e.g., thermal NOx) concentration to less than 50 million ^-1.

 A more complete assessment of the proposed invention can be given and many of its advantages can be better understood if you read the detailed description of the invention together with a consideration of the accompanying drawings. In the accompanying drawings, the same designations refer to the same or similar elements.

 In FIG. 1, one of the preferred variants of the invention is shown in longitudinal section.

 In Fig.2 presented in Fig.1 the device is shown in section along the line aa.

 In Fig.3, the device shown in Fig.1 is shown in section along the line BB.

 In Fig. 4, the device shown in Fig. 1 is shown in section along the line BB.

 In Fig.5 presented in Fig.1 the device is shown in section along the line GG.

 Figure 6 shows a functional diagram of one of the preferred variants of the invention.

 The aim of the invention is to solve the above problems by creating a parallel multistage thermal pump using the principles of evaporation and condensation of water, which would circulate hot water and suck in cold water without the help of other circulation or water pumps, the operation of which would not cause soot formation in successive sections of the combustion chamber when burning fuel, and at the same time, a significant decrease in the degree of formation of toxic gases would be ensured.

 The above goal can be achieved by creating a parallel multi-stage thermal pump proposed by the present invention using the principles of evaporation and condensation of water, including the following elements: a combustion chamber connected by more than two steps to a cylindrical steam generator chamber having a connecting exhaust pipe, a high temperature chimney, a water channel, made with the possibility of providing a change in the direction of movement of water, and a check valve for discharged water, at The pump constructively includes a combustion chamber inside it, located on both sides of this combustion chamber, a front surface water reheating chamber and a rear surface water reheating chamber, a burner installation hole, a third air channel, a through hole, a reverse combustion plate related to the front surface, and a plate of reverse combustion related to the rear surface, configured to release gaseous products of combustion at the lowest point of the cam combustion after five contact of fuel with air, a pumping means having a pump chamber, a connecting suction pipe, a connecting steam pipe, an external steam exhaust pipe and an internal steam exhaust pipe located in the upper part of each of the above steam generator chambers, which surround the combustion chamber, condensation chamber, having a non-return valve for intake water, a connecting water tube, a sound-suppressing cross-shaped shock-absorbing plate, a first anti-noise grid, and a second an anti-noise grid, a perforated separation plate, a non-return air valve and heat-insulating material that prevents heat transfer between the pump chamber and the condensation chamber, an economizer having a low-temperature chimney and a flow reversal separation plate made around the periphery of the above pumping means and connected to the connecting water pipes, and connecting means configured to provide a connection to a water suction channel connecting to nalom discharged water, the outlet tube and with the possibility to provide air communication with the successive sections of the external circulation through the suction port, an outlet port and the chimney.

 Next, with reference to the accompanying drawings, one of the preferred variants of the invention is considered. In addition, the following description will fully understand the essence of the invention. It should be noted that in the present description, in order to avoid introducing details that could obscure the subject of the invention, details are omitted regarding the description of known functions and known structural elements.

 As shown in figure 1, the above structure is used as a parallel device having more than two stages in the longitudinal direction, and near the multi-stage pumping device there should be an economizer 1 connected to a low-temperature chimney 2 of the upward exhaust gas and having a separation plate for reversing the flow 3. As shown in figure 2, the upper part of the cylindrical steam generating chamber 4 is connected to the connecting exhaust pipe 5 and the chimney 6 and structurally contains baa combustion chamber 7. According to the invention implemented pump device structure consisting of a pump chamber 8 at the bottom of the condensation chamber 9 and in its upper part. As shown in Fig.6, in accordance with the invention, when filling the internal and external heat exchangers (radiators) with water in the direction of the arrow, shown by the solid line, the air in the device only rises and is released outward through the check valve 10 and the circulating successive sections are filled with water. As mentioned above, after filling the device and the circulating successive sections with water, the high temperature resulting from the combustion of a fuel such as gas or oil in the combustion chamber 7 first acts on the periphery of the combustion chamber 7 and the high temperature chimney 6, so that water is in the steam generator chamber 4 may go into a vapor state. The resulting steam, as mentioned earlier, is collected in the upper part of the pump chamber 8, penetrating there through the connecting steam pipe 11, while the water in the pump chamber 8 is supplied to the lower part of the steam generating chamber 4 through the connecting exhaust pipe 5, so that the direction of the water flow can be changed in the channel with the changing direction of the water flow 12 with the formation of sediment in the steam-generating chamber 4. Therefore, the above steam passes through the check valve of the discharged water 13 and the connecting channel of the discharged water 14, is reheated from the reheating chambers of the discharged water 15-1 and 15-2, discharged from the device through the exhaust pipe 16 and the outlet 17, radiates thermal energy in the radiator and rushes by gravity into the water tank. Then, when the amount of steam collected in the lower part of the inner steam exhaust pipe 18 increases and the interface between water and air reaches the lower part of the inner steam exhaust pipe 18, steam under water pressure corresponding to the height of the water column acting on the lower part of the inner steam exhaust pipe 18 instantly discharged into the lower part of the condensation chamber 9 through the external steam exhaust pipe 19 and the internal steam exhaust pipe 18.

 At this point, when the steam is released, a small amount of water comes out of the steam and a sharp sound occurs, caused both by the rapid outflow of the steam, and by vibrations and noises arising in the event that there is rapid condensation upon contact of the steam with cold water. In order to eliminate a sharp sound, a cruciform shock-absorbing plate 20, a first anti-noise mesh 21 and a second anti-noise mesh 22, which have a conical shape and are installed with the possibility of damping the vibrations and noise arising from direct contact of steam with water, are used, as mentioned above. The largest part of the steam, freed from noise and vibration, as described above, condenses in the form of water in the lower part of the condensation chamber 9, and the steam that has not condensed here completes its condensation when passing through the perforated separation plate 23 provided with small holes and installed in the center of the condensation chamber 9. And when the amount of condensing steam exceeds the amount of evaporating water, the pressure inside the device decreases, as a result of which water from the water tank is absorbed through h suction port 24, economizer 1, water suction channel 25, water suction check valve 26, upper part of the condensation chamber 9, connecting water pipe 27, lower part of the condensation chamber 9, connecting suction pipe 28 and pump chamber 8. Thus, with continued the repetition of the processes of vaporization under the action of heat from fuel combustion, collecting the generated steam in the upper part of the pump chamber 8, instantaneous release of steam into the lower part of the condensation chamber 9 and condensation of steam, i.e. rashchenija it again into water, the device of the present invention provides the pumping of water without the aid of outside circulation apparatus. Between the pump chamber 8 and the condensation chamber 9, heat-insulating material 29 preventing heat transfer is located.

 The air generated inside the device during operation of the pump according to the invention is discharged through the check valve 10 into the atmosphere at the end of the exhaust process, and due to the occurrence of reduced pressure, the suction process starts, thereby preventing suction from the check valve 10. Water heated by the chamber combustion 7, sequentially passes, forcibly descending, from the water-suction channel 25 to the connecting channel of the discharged water 14 through a water suction valve 26, a condensation chamber 9, a connecting water pipe 27, a connecting suction pipe 28, a pump chamber 8, a connecting exhaust pipe 5, a steam generating chamber 4, a channel with a variable flow of water 12 and a non-return valve for discharging water 13, and the remaining after condensation steam is released into the atmosphere, passing through the steps of condensation of water as it moves upward along the following path: connecting steam pipe 11, the upper part of the cross-shaped shock-absorbing plate 20, the first anti-noise grid 21, and the second I have an anti-noise grid 22, the lower part of the condensation chamber 9, a perforated separation plate 23 and a non-return air exhaust valve 10. In addition, the above-described device for sucking and discharging water is installed in parallel in the presence of multi-stage, which reduces the vibration of the circulating serial sections and increases the smoothness of operation.

 Reverse combustion in the device according to the invention differs from conventional reverse combustion in that under the influence of the kinetic energy of the liquid, a reduced pressure occurs and the front and rear parts of the combustion chamber “reverse” (as if swapped due to the alternating flow direction) providing five-fold contact of fuel and air due to which conditions are created for complete combustion.

 The burner of the device according to the invention provides the mixing of fuel with air with the occurrence of reactive force when passing the first air coming from the air blower through the control valve, with reverse combustion of the second air in front of the combustion chamber 7 and with reverse combustion of the third air in the rear of the combustion chamber 7 as with a conventional burner. As shown in figure 1, the first air and the second air entering the hole for installing the burner 30, swirl, in the combustion chamber 7 there is a combustion of fuel, between the reverse-burning plate 31 related to the front surface and the exhaust water re-heating chamber related to the front surface 15-1, a reduced pressure occurs when the first air and second air are passed through the center of the reverse combustion plate 31 related to the front surface of the plate at a high speed, whereby incomplete combustion of gaseous products in contact with the inside of the steam generating chamber 4 ensures that the second air contacts the combustion products with the participation of the second air. After this, the third air is heated in the connecting tube of the third air 32 and the channel of the third air 33 passes through the through hole 34 and the center of the reverse surface of the reverse combustion plate 35 at high speed, so that a reduced pressure is generated between the rear surface of the reverse combustion plate 35 and related to the rear surface of the reheating chamber of the discharged water 15-2, thereby ensuring the absorption of gaseous products of incomplete combustion, gathering in the upper part of the combustion chamber 7, and contact with the third air to ensure complete combustion. Soot generated by the combustion of combustible gas burns out, as mentioned earlier, so that relatively light unburned gas is collected in the upper part of the combustion chamber 7, which burns when it is reversed using a reversible combustion plate. In addition, after complete combustion of the combustible gas, the largest part of the heat generated from the combustion is transferred to the steam chamber 4 when the gaseous products of combustion pass through a high temperature chimney 6 connected to the lowest part of the combustion chamber 7, while the remaining heat from the upper part of the steam chamber 4 rises along the exhaust gas ascension channel 36, then lowers to the bottom of the separation plate 37 made of insulating material, then rises again at a low economizer chimney 2 2. After that, when the remaining gas flows in the following order: pump chamber 8, economizer 1 and condensation chamber 9, again descending through the space between condensation chamber 9 and economizer 1, air is discharged through the chimney 38 into the atmosphere . Thus, the flow of gaseous products of combustion has a direction opposite to that of water, which greatly increases the heating efficiency. The design is also covered with insulation 39.

 As can be understood from the foregoing, the present invention has the advantage that due to the combination of the heat-saving design and the combustion method, more complete combustion with less heat loss is provided, while in accordance with the combustion method according to the invention, a conventional and well-known burner is used and no changes are made or improvements to the part of the device associated with the combustion of fuel, and provides a continuous exit of hot water without the help of other circulation Asosa or water pump, whereby the device is designed to supply hot water or hot water boiler in comparison with the prior art varies revolutionary way, and due to cheapening of production costs is ensured cheap hot water.

 What has been described above is considered as preferred variants of the invention, however, it will be understood by those skilled in the art that various changes and modifications are possible, some elements may be replaced by others without increasing the true scope of the invention. In addition, without going beyond the scope of the invention, many changes can be made in order to adapt to the invention. Therefore, it is clear that the invention is not limited to the specific options in accordance with which the invention is carried out in the best way, and the invention includes all variants that fall within the scope of the claims, which is defined by the following claims.

Claims (1)

 1. A parallel multistage thermal pump using the principles of water evaporation and condensation, comprising a combustion chamber connected by more than two steps to a cylindrical steam generator chamber having a connecting exhaust pipe, a high temperature smoke pipe, a water channel configured to provide a change in the direction of movement of water, and a check valve for discharged water, while the pump structurally includes a combustion chamber made inside it, located on both sides of this chamber the combustion chamber for reheating the water of the front surface and the chamber for reheating the water of the rear surface, the hole for installing the burner, the third air channel, the through hole, the reverse burning plate related to the front surface, and the reverse burning plate related to the rear surface the release of gaseous products of combustion at the lowest point of the combustion chamber after five times the contact of fuel with air, pumping means having a pumping chamber, a connector a suction pipe, a connecting steam pipe, an external steam pipe and an internal steam pipe located in the upper part of each of the above steam generating chambers that form the combustion chamber, a condensation chamber having a suction water check valve, a connecting water pipe, a sound canceling cross-shaped damping plate, the first anti-noise screen, second anti-noise screen, perforated dividing plate, non-return air exhaust valve heat transfer, heat-insulating material located between the pump chamber and the condensation chamber, an economizer having a low-temperature chimney and a flow reversing dividing plate made on the periphery of the above pumping means and connected to the connecting water pipes, and connecting means configured to provide a connection to the channel water absorption by the connecting channel of the discharged water, the exhaust pipe and with the possibility of providing air communication with after ovatelnymi sections external circulation through the suction port, an outlet port and the chimney.

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