RU2153622C1 - Device for storage and delivery of cryogenic products - Google Patents

Abstract

FIELD: cryoengineering. SUBSTANCE: filling-up and draining pipelines and wires running from transducers in device for storage and delivery of cryogenic products, in section between external and internal casings are localized in one zone enclosed in auxiliary vacuum-tight coating. Coating with adjacent sections of device internal and external casings forms closed vacuum-tight cavity which is provided with auxiliary evacuation valve. EFFECT: enhanced safety of operation. 1 dwg

Description

 The invention relates to cryogenic technology and is intended for storage and supply of cryogenic products to consumers, for example, for supplying hydrogen and oxygen stored at cryogenic temperatures to an electrochemical generator (ECG) of a power plant (EC) based on hydrogen-oxygen fuel cells intended for installation in submarines, in addition, it can be used in space technology to supply cryogenic products to consumers installed on spacecraft (SC), as well as in m farm in the autonomous power plant based on hydrogen-oxygen fuel cells, intended for use in areas where laying of transmission lines is difficult.

 A device for storing and supplying hydrogen and oxygen to the ECG EC is accepted (see "Power Plants and Power Systems for Spacecraft Based on Hydrogen-Oxygen Fuel Cells" edited by MV Melnikov, M., GONTI-4, 1970 , p. 43-89).

 The device includes cryogenic containers for storing hydrogen and oxygen, each of which contains a thermally insulated inner shell with sensor equipment located inside it, enclosed in a vacuum-tight outer shell with an evacuation valve installed on it, filling and drainage pipelines, safety and shutoff valves.

 There is also known a device for storing and supplying liquid hydrogen, selected as a prototype (see "Questions of deep cooling", a collection of articles edited by MPMalkov.- M .: Publishing house of foreign literature 1961, S. 409-413).

 The device contains a thermally insulated inner shell with sensor equipment located inside it, enclosed in a vacuum-tight outer shell with a vacuum valve installed on it, refueling and drainage pipelines, safety and shutoff valves.

 The disadvantage of the analogue and prototype is that they do not provide maintainability, and, therefore, the restoration of the device’s operability in the most likely failure-loss of the tightness of the heat-insulating cavity (the cavity between the inner and outer shells) of the device. The reason for the loss of tightness is mainly a violation of the tightness of pipelines in the area between the shells of the device. In this section, in order to reduce heat inflow through pipelines, they are made in the form of coils or with bellows inserts, which increases the length of the heat transfer path. During long-term operation under conditions of overload during vibration of the coils in the places of their welding into the shells, leakproofness can be broken, and it can also be broken in the places of welding of bellows and electroheater sockets to which the wires from the sensors of the equipment are soldered.

 Devices for storing and supplying hydrogen and oxygen, which are part of the EU installed on a submarine, must be operated for 25 years under overload conditions of up to 10 g, therefore, the probability of loss of tightness in the above places is high. To eliminate leaks in these places, a complete disassembly of the device is required: dismantling the outer shell of the thermal insulation and everything that is installed on the shells. In the conditions of a submarine, carrying out such repairs is inconvenient and impractical, because it will take a very long time and the boat will be idle. Therefore, in this case, the device must be replaced, which, firstly, is expensive, and secondly, removing the device from the energy compartment of the boat and installing a new one also takes a long time.

 Another disadvantage of the known devices is that in case of loss of tightness of the heat-insulating cavity, and, consequently, loss of vacuum in it, the pressure of the stored cryogenic product will increase rapidly to the level of operation of the safety valve. If at this time the boat is at a depth of maximum immersion, for example 300 m, then its ascent time may be less than the time of pressure rise to the level of operation of the safety valve. In this case, the cryogenic product will be drained into the surrounding water area. When draining a cryogenic product whose temperature is lower than the temperature of the water, the resulting ice can clog the outboard opening of the emergency discharge pipeline. Under these conditions, the pressure of the cryogenic product may increase above the maximum design level, which will lead to an emergency in the energy compartment of the boat, i.e., known devices with a loss of vacuum in the insulating cavity do not provide safe operation conditions.

The rapid increase in the pressure of the cryogenic product is due to the fact that when the vacuum is lost, the effective thermal conductivity of the vacuum multilayer insulation increases from 1 • 10 ^-4 to 2 • 10 ^-1 kcal / m • h • deg (see G.N. Napalkov, " Thermal protection of tanks with cryogenic rocket fuel ", Handbook, part 1, M., GONTI-4, 1973, Fig. 33), i.e. 2000 times. The total heat gain from the environment to the stored cryogenic product is made up of heat gain through thermal bridges (supports, pipelines, wires) and heat gain through thermal insulation. When applying vacuum multilayer thermal insulation, the heat gain through it does not exceed 50% of the total heat gain. At this level of heat gain through thermal insulation (50% of the total heat gain) with a loss of vacuum, and, consequently, an increase in heat gain through thermal insulation by a factor of 2000, the total heat gain increases ~ 1000 times. Such an increase in heat gain will lead to a rapid increase in pressure and to the aforementioned consequences.

 The objective of the present invention is to ensure the maintainability of the device for storage and supply of cryogenic products and increase the safety of its operation.

 The essence of the invention lies in the fact that in a device for storing and supplying cryogenic products containing a thermally insulated inner shell with sensor equipment located in it, enclosed in a vacuum-tight outer shell with a vacuum valve installed on it, filling and drainage pipelines, safety and shutoff valves , the mentioned pipelines and wires from the sensor equipment in the area between the outer and inner shells are localized in one zone, which is enclosed in an additional a vacuum-tight shell, which forms, with adjacent sections of the inner and outer shells, a closed vacuum-tight cavity, which is equipped with an additional vacuum valve.

 The technical result consists in the fact that, in comparison with the technical solutions known today, the newly created design ensures the maintainability of the device for storing and feeding cryogenic products and increases the safety of its operation.

This is achieved due to the localization in one zone of all pipelines intersecting the space between the inner and outer shells and wires from the sensor equipment, output from the inner shell to the outer one using electrohermo connectors or by arranging them inside special pipelines and enclosing these pipelines, wires and electrical connectors in an additional a vacuum-tight shell, which forms, with adjacent sections of the inner and outer shells, a closed vacuum-tight cavity that sleeps Byzhena valve evacuation. As a result of this, if the tightness of pipelines, bellows or electrical connectors is violated, to eliminate it, you only need to open the upper bottom of the newly formed vacuum-tight cavity and eliminate the leakage, and not to replace the entire device, as in the well-known technical solutions, which allows reducing the cost of restoration work by orders of magnitude and their execution time. In addition, in case of violation of the tightness of pipelines, the vacuum in the main volume of the insulating cavity is not violated. The area of the localized zone is 1-2% of the entire area of the inner shell, for example, for a device for storing and supplying liquid hydrogen in the amount of ~ 1.5 tons, installed as part of the remote control on a submarine, the entire area of the inner shell is 55 m ² , and the area of the localized zone is 0.8 m ² , i.e. ~ 70 times smaller than the entire area. Therefore, if, in known devices, the heat gain to the cryogenic product, when the vacuum is lost in the heat-insulating cavity, increases, as mentioned above, by 1000 times, then in the proposed design it increases by 1000: 70 = 14.3 times. As a result, in the proposed design, the pressure growth rate will be significantly lower. After detecting an unauthorized increase in pressure, the boat will have time to emerge from any depth, and the cryogenic product will be drained under control, which will prevent clogging of the outboard opening of the emergency discharge pipeline and exclude possible emergency situations during discharge, i.e. increase operational safety.

 The invention is illustrated in the drawing, which shows a diagram of a device for storage and supply of cryogenic products.

 The device comprises an inner shell 1, on which a vacuum-multilayer thermal insulation is applied 2. The inner shell 1 is fixed in a vacuum-tight outer shell 3 on the supports 4. The device is equipped with a refueling pipe 5 with a bellows insert 6 in the area between the shells and the drainage pipe 7, which the section between the shells is made in the form of a coil 8. The pipelines 5, 7 are equipped with electro-pneumatic valves 9, 10, respectively. In the inner shell 1, a temperature sensor 11 is installed, an internal heat source, for example er electric heater 12, quantity sensor 13. Sensors 11, 13 and electric heater 12 are connected via wires 14 to an electrohermo connector 15 welded into the inner shell 1, which is connected by wires 16 to an electrohermo connector 17 welded into the outer shell 3. Pipelines 5, 7 and electrical connectors 15, 17, connected by wires 16, are concentrated in one zone and enclosed in an additional vacuum-tight shell 18, which, with adjacent sections of the inner and outer shells, respectively 19, 20, forms a closed vacuum-tight a cavity in which a vacuum-multilayer thermal insulation 21 is applied to a portion 19 of the surface of the inner shell 1. On the outer shell 2, a main vacuum valve 22 and an additional vacuum valve 23 are installed on the portion 20 of the outer shell 3. The device is equipped with a safety valve 24 and a pressure sensor 25 .

 The device operates as follows.

The electrovalves 9, 10 are opened and cooling is performed and then the cavity of the inner shell 1 is filled with a cryogenic product (liquid hydrogen or liquid oxygen). After refueling, the electro-pneumatic valves 9, 10 are closed, the electric heater 12 is turned on and the pressure rises to the working level, for example, up to 10 kgf / cm ² , after which the electric heater 12 is turned off. A cryogenic product is sampled in an ECG. Both liquid and vapor phases can be taken off, for which valves 9 or 10 open. With increasing pressure, when the flow rate is small, the vapor phase is taken away, and with a large flow rate the pressure drops and the liquid phase is taken. Thus, by regulating the selection of phases and turning the electric heater 12 on and off, pressure is maintained during the selection process in a predetermined controlled operating range, for example, 8-10 kgf / cm ² . If during operation the tightness, for example, bellows 6, is lost, then there will be a loss of vacuum in a closed vacuum-tight cavity formed by a vacuum-tight shell 18 and sections 19, 20 of the inner and outer shells, respectively. As a result, in this local zone there will be increased heat gain through thermal insulation, which will lead to an off-design pressure increase, which is detected by the pressure sensor 25. The pressure growth rate in the proposed device will be much lower than in known devices, because the vacuum will be lost only in a closed additional vacuum-tight cavity, the bottom area of which - section 19 - is not more than 1.5% of the entire area of the shell 1, and increased heat gain through thermal insulation will only be on this area. The time of pressure growth before the safety valve actuates, for example, up to 35 kgf / cm ² (such a pressure level of the pressure relief valve is necessary so that the cryogenic product can be discharged at any possible immersion depth, for example 300 m), will not be minutes, as in known devices, and from 1.5 to 5 hours, depending on the amount of cryogenic product at that moment. After the ascent of the boat, the condition of the intake opening of the discharge pipeline will be monitored so that it is not clogged, while in addition to discharging the cryogenic product through the safety valve, the cryogenic product can be discharged through pipeline 5, which cannot be done under immersion conditions. All this increases the safety of operation. To eliminate leaks after removing the cryogenic product from the cavity of the shell 1, it is only necessary to open the upper bottom 20 of the additional vacuum-tight cavity, remove the heat insulation from it and replace the bellows 6, and not remove the failed device for storing and supplying cryogenic products from the energy compartment and install a new one.

 Thus, in comparison with the known technical solutions, the proposed device due to the localization in one zone of all pipelines crossing the space between the inner and outer shells and wires from the sensors of the equipment output from the inner shell to the outer one by means of electrical seals and the conclusion of these pipelines, wires and electrical connectors in an additional vacuum-tight shell, forming a closed vacuum-tight cavity with adjacent sections of the inner and outer shells, is equipped with a female vacuum valve, allows to ensure the maintainability of the device with minimizing the time and cost of repairs and to improve the safety of operation of the device and the whole boat.

Claims (1)

 A device for storing and supplying cryogenic products, containing a thermally insulated inner shell with sensor equipment located inside it, enclosed in a vacuum-tight outer shell with a vacuum valve installed on it, filling and drainage pipelines, safety and shutoff valves, characterized in that the said pipelines and the wires from the sensor equipment in the area between the outer and inner shells are localized in one zone, which is enclosed in an additional vacuum-tight shell Ku, defining with surrounding portions thereto the inner and outer shells a closed vacuum-tight cavity which is provided with an additional vacuum valve.