EA039793B1 - System for recycling and recovery of waste heat for mine return air - Google Patents

Abstract

The invention relates to a system for recycling and recovery of waste heat in mine return air, comprising an air guide apparatus, an air heat exchanger assembly, a water heat exchanger assembly, a hot water transmission and distribution apparatus, and a hot water usage apparatus. One end of an air duct of the air guide apparatus connects to a mine return air shaft, and another end of the air duct connects to the air heat exchanger assembly; the hot water transmission and distribution apparatus comprises a hot water supply pipe and a hot water return pipe, one end of the hot water supply pipe and one end of the hot water return pipe connecting to the water heat exchanger assembly, and another end of the hot water supply pipe and another end of the hot water return pipe connecting to the hot water usage apparatus; the air heat exchanger assembly connects to the water heat exchanger assembly by means of a refrigerant pipe, the air heat exchanger assembly is configured so as to absorb heat in return air, and the water heat exchanger assembly is configured so as to transmit the heat absorbed by the air heat exchanger assembly into circulating water in the hot water transmission and distribution apparatus.

Description

Cross-reference to related applications

For an invention based on international application PCT/CN 2019/098639 filed on July 31, 2019, priority is claimed based on applications nos. 201811220168.8, 201811220194.0 and

201811220158.4 filed October 19, 2018 with the China Patent Office, the entire contents of which are hereby incorporated by reference.

Technical field

The present invention relates to the field of mine waste heat recovery, and in particular to a waste heat recovery and recovery system for mine exhaust air.

State of the art

Mine exhaust air is a high-quality waste heat resource, but the exhaust air of an existing mine is usually directly discharged into the atmosphere, and a large amount of waste heat resources are not used efficiently, which not only causes energy waste, but also increases the greenhouse effect.

In the prior art, in the waste heat recovery and utilization system for the exhaust air of mine, the exhaust air of the mine is mainly atomized by the spray water so as to absorb the heat in the exhaust air, the heat absorbing spray water is stored in the sump, and the spray water is made into hot water with more high temperature by means of a heat pump using the heat of water and used in the mining area.

In this technology, the recovery system formed by the atomization equipment, the water collection tank and the water heat pump equipment has a complex overall structure, the complexity of the structure increases and the production cost increases.

The above information is described in the background section only to enhance understanding of the basis of the present invention, and therefore it may include information that does not constitute prior art that is known to those skilled in the art.

The essence of the invention

One main object of the present invention is to overcome at least one of the aforementioned shortcomings in the prior art and provide a waste heat recovery and recovery system for mine exhaust air with a simple structure and a high recovery rate.

In order to achieve the object of the invention, the following technical solutions are adopted in the invention.

According to one aspect of the invention, a waste heat recovery and recovery system for exhaust mine air is provided, which includes an air flow directing device, an air heat exchange unit, a water heat exchange unit, a hot water transport device, and a hot water recovery device; one end of the air duct of the air flow directing device is connected to the ventilation shaft of the spent mine air, and the other end of the air duct is connected to the air heat exchange unit; the hot water supply and distribution device includes a hot water supply pipe and a hot water return pipe, one end of the hot water supply pipe and one end of the hot water return pipe are connected to the water heat exchange unit, and the other end of the hot water supply pipe and the other end of the hot water return pipe connected to a hot water recovery device; the air heat exchange unit is connected to the water heat exchange unit via a refrigerant pipeline, the air heat exchange unit is configured to absorb exhaust air heat, and the water heat exchange unit is configured to conduct heat absorbed by the air heat exchange unit into water circulating in the hot water transport device.

According to one embodiment of the present invention, the air heat exchanger includes an evaporator and a compressor, where the compressor is connected to the evaporator.

According to one embodiment of the present invention, the water heat exchange assembly includes an expansion valve and a condenser, where the expansion valve, evaporator, compressor and condenser are connected in series one after the other.

According to one embodiment of the present invention, the evaporator includes at least four rows of plate sets, and these at least four rows of plate sets are stacked and corrugated.

According to one embodiment of the present invention, the number of plate sets comprises four rows and these plate sets are shaped like an M or a W.

According to one embodiment of the present invention, each set of plates includes a plurality of plates spaced apart and the distance between two adjacent plates is 3-6 mm.

According to one embodiment of the present invention, the distance between two adjacent plates is 4-5 mm.

According to one embodiment of the present invention, the distance between two adjacent plates is 4.2 mm.

According to one embodiment of the present invention, the water heat exchange unit includes a water inlet and a water outlet, a hot water supply pipe is connected to the water outlet, and a hot water return pipe is connected to the water inlet.

According to one embodiment of the present invention, the air heat exchange assembly includes a first side surface and a second side surface, wherein the first side surface is in contact with outside air and the second side surface is in contact with the exhaust air in the air flow directing device.

According to one embodiment of the present invention, the hot water recovery device is at least one of a mine inlet air preheater, a shower device, and a heating device.

According to one embodiment of the present invention, the air flow guide device includes a horizontal guide air duct and a curved guide air duct, two ends of the horizontal guide air duct are respectively connected to the exhaust mine air ventilation shaft and a curved guide air duct, and the other end of the curved guide air duct is connected to the air heat exchange unit.

According to one embodiment of the present invention, the air flow directing device further includes a supply air pipe that is installed at the mouth of the exhaust mine air ventilation shaft with upward expansion, the supply air pipe is connected to the horizontal guide air duct and the supply air pipe is hermetically connected to the inlet of the exhaust mine air ventilation shaft. and a horizontal guide air duct, where the horizontal guide air duct is connected to the bottom of the shaft by means of support rods, and the horizontal guide air duct is vertical to the axis of the supply air pipe.

According to one embodiment of the present invention, the air flow directing device further includes a horizontally located service platform, and the service platform is connected to the shaft floor by means of support rods.

According to one embodiment of the present invention, at least one ventilation door is additionally located on the air flow directing device.

According to one embodiment of the present invention, the surface of the upper end of the supply air pipe coincides with the plane of the service platform.

According to one embodiment of the present invention, in the air flow directing device, a guide plate is additionally located, which is in the form of an arch, and the concave surface of the guide plate is turned towards the exhaust mine air, and it is used to direct the exhaust mine air to the outlet.

According to one embodiment of the present invention, the hot water supply and distribution apparatus further includes a circulating water pump assembly used to circulate circulating water in series between the water heat exchange assembly, the hot water supply pipe, the hot water recovery device, and the hot water return pipe.

According to one embodiment of the present invention, a check valve is located at the water outlet end of the circulating water pump assembly.

According to one embodiment of the present invention, the hot water transport device further includes an auxiliary water supply device for supplying circulating water.

According to one embodiment of the present invention, the hot water transport device further comprises a water softener to reduce the hardness of tap water.

According to one embodiment of the present invention, the system further includes an automatic control system, and the automatic control system is used to control the operating conditions of the waste heat recovery and recovery system for the mine exhaust air.

According to one embodiment of the present invention, the refrigerant piping is a copper pipe.

As can be seen from the above technical solutions, the advantages and positive effects of the waste heat recovery and utilization system for exhaust mine air are as follows.

Through the use of air heat pump technology, the exhaust mine air is in direct contact with the air heat exchange unit, heat is transferred from the exhaust air to the air heat exchange unit, and then the heat in the exhaust air is transferred to the circulating water through the water heat exchange unit. Compared with the prior art, the construction of the water atomizing device and the water collection tank is omitted so that the structure of the recovery system is simpler.

In addition, according to the present invention, the heat can be transferred from the mine exhaust air to the circulating water only by means of a heat pump using the heat of the air,

- 2 039793 while compared to the prior art, in which heat is first supplied by atomized water and then the heat is transferred to the circulating water using a heat pump using water heat, the system according to the invention has a greatly improved heat recovery coefficient of exhaust mine air.

Brief description of the drawings

The above and other features and advantages of the present invention will become clearer by a detailed description of examples of its embodiment with reference to the attached drawings.

Fig. 1 is a schematic diagram of a waste heat recovery and recovery system for exhaust mine air according to one embodiment;

fig. 2 is an operational schematic diagram of an air heat exchange unit and a water heat exchange unit according to one embodiment;

fig. 3 is another schematic diagram of an air heat exchange unit and a water heat exchange unit according to one embodiment;

fig. 4 is a schematic representation of an air heat exchanger evaporator plate assembly according to one embodiment;

fig. 5A is a schematic representation of a four-row M-shaped plate stack according to one embodiment;

fig. 5B is a schematic representation of a four-row W-shaped plate stack according to one embodiment;

fig. 6 is a front view of a mine air flow directing device according to one embodiment;

fig. 7 is a left side view of FIG. 6.

The position numbers in the drawings are as follows:

- air flow guide device, 11 - horizontal air guide duct, 12 curved air guide duct, 13 - supply air pipe, 14 - ventilation door, 2 air heat exchange unit, 21 - refrigerant piping, 22 - first side surface, 23 second side surface, 24 - evaporator, 241 - evaporator tube, 242 - plate, 243 - first set of plates, 244 - second set of plates, 245 - third set of plates, 246 - fourth set of plates, 25 - compressor, 3 - water heat exchanger, 31 - inlet for 32 - water outlet, 33 - condenser, 34 - expansion valve, 4 - hot water transport device, 41 hot water supply pipe, 42 - hot water return pipe, 43 - water circulation pump unit, 431 - water circulation pump, 432 - non-return valve, 433 - filter, 434 - flexible connection, 44 - additional supply pump, 45 - water softener, 451 - water softener tank, 452 - brine tank, 5 - device hot water disposal unit, 6 - exhaust mine air ventilation shaft, 7 - guide plate, 8 - support rod, 9 - shaft mouth, 10 - service platform, 101 fence, F - shaft sole.

Detailed description of the invention

The following describes the embodiments more fully with reference to the accompanying drawings of the embodiments. However, the invention can be embodied in many different forms and should not be construed as being limited to the embodiments set forth herein, rather, these embodiments are provided so that this description is exhaustive and complete and fully conveys the idea of exemplary embodiments to those skilled in the art. Like reference numerals in the drawings denote the same or similar structures and thus their detailed descriptions are omitted.

Although relative terms such as upper and lower are used in this description to describe the ratio of one component to another component of a drawing, these terms are used in this description only for convenience, for example, in the direction of the examples shown in the drawings. It should be understood that if the device shown in the drawings is turned upside down, the component described as above becomes the component described as below. Other relative terms such as top, bottom, and the like also have similar meanings. The terms singular and indicated are intended to mean that there are one or more elements/components/etc., the terms containing and having are used in an inclusive sense and they mean that additional elements/components/etc. may be present. . in addition to the listed elements/components/etc., the terms first, second, third and fourth, etc. are used only as markers and are not intended to limit the number of their objects.

The idea of the present invention is as follows: by using the air heat pump technology, the heat in the mine exhaust air is absorbed by the air heat exchange unit 2, and the heat is conducted into the circulating water by the water heat exchange unit 3, so that the heat is used to preheat the mine air inlet, irrigation of the mining area, heating of the mining area, or other hot water utilization device in the mining area, which replaces conventional coal, fuel oil or electric power, and achieves the effect of saving energy.

Some embodiments of the present invention are described below in detail with reference to the accompanying drawings, and the features of the embodiments described below may be combined with each other without conflict.

With regard to FIG. 1, in this embodiment, the waste heat recovery and recovery system for mine exhaust air of the present invention includes an air flow directing device 1, an air heat exchange unit 2, a water heat exchange unit 3, a hot water transport device 4, and a hot water recovery device 5. One end of the air duct of the air flow directing device 1 is connected to the exhaust mine air ventilation shaft 6, and the other end of the air duct is connected to the air heat exchange unit 2. The hot water distribution device 4 includes a hot water supply pipe 41 and a hot water return pipe 42, and one ends of the pipe The hot water supply pipes 41 and the hot water return pipes 42 are connected to the water heat exchanger unit 3, and their other ends are connected to the hot water recovery device 5 . The air heat exchange unit 2 and the water heat exchange unit 3 can be connected by a copper pipe 21. The air heat exchange unit 2 is used to absorb the heat of the exhaust air, and the water heat exchange unit 3 is used to conduct the heat absorbed by the air heat exchange unit 2 to the circulating water flowing in the device 4 hot water transportation.

Specifically, as shown in FIG. 2 and 3, air heat exchanger 2 may include an evaporator 24 and compressor 25, and water heat exchanger 3 may include condenser 33 and expansion valve 34. Evaporator 24, compressor 25, condenser 33, and expansion valve 34 comprise an air heat pump unit. The evaporator 24, the compressor 25, the condenser 33 and the expansion valve 34 can be connected by a refrigerant line 21. The refrigerant pipe 21 may be a copper pipe or a metal pipe made of other materials, and in this embodiment, the refrigerant pipe 21 is a copper pipe. Copper refrigerant piping has the advantages of low price, soft structure and easy bending, etc. At the same time, the copper refrigerant pipe is located in the heat exchanger equipment, so that the mass of the heat exchanger equipment is reduced and the corrosion resistance is improved.

The copper pipe 21 is filled with a heat transfer medium. The heat transfer medium may be isobutane, n-butane, freon, or the like. or a combination of the described substances. The boiling point of the heat transfer medium at normal pressure is very low at -40°C, the freezing point is below -100°C, and the substance is in a liquid state under the condition of reduced temperature. Therefore, when the heat transfer medium comes into contact with the mine exhaust air (the temperature is approximately 8°C), the heat transfer medium evaporates rapidly.

The air heat pump unit may include an evaporator 24, a compressor 25, a condenser 33, and an expansion valve 34 connected in series. The evaporator 24 is connected to the compressor 25, the condenser 33 and the expansion valve 34 via a refrigerant line 21. Specifically, the outlet end of the evaporator 24 is connected to the inlet end of the compressor 25 through a refrigerant line 21, and the inlet end of the evaporator 24 is connected to the outlet end of the expansion valve 34 through a single refrigerant line.

The connection ratio of the air-heated heat pump is as follows: the outlet end of the evaporator 24 is connected to the inlet end of the compressor 25 by means of a refrigerant pipe 21, the outlet end of the compressor 25 is connected to the inlet end of the condenser 33 by a pipe, the outlet end of the condenser 33 is connected to the inlet end of the expansion valve 34 by pipes and the outlet end of the expansion valve 34 is connected to the inlet end of the evaporator 24 through a refrigerant pipeline. Thus, evaporator 24, compressor 25, condenser 33 and expansion valve 34 form a closed circuit. Meanwhile, the heat transfer medium such as isobutane, n-butane, freon, etc. or a combination of the described substances, fills the pipes. The boiling point of the heat transfer medium at normal pressure is very low, and the heat transfer medium can quickly evaporate after contact with the exhaust mine air, so that the waste heat is absorbed by the exhaust mine air.

The operating principle of how to transfer the heat of the mine exhaust air to the circulating water when the air heat exchange unit 2 and the water heat exchange unit 3 are operated will be described in detail below.

The heat transfer medium in the evaporator 24 absorbs the heat of the mine exhaust air, the heat transfer medium is evaporated in the evaporator 24, the heat transfer medium in the low temperature and low pressure state is compressed by the compressor 25, then it becomes a gas in the high temperature and high pressure state, and this gas is in the state of high temperature and high pressure are sent to the condenser 33. Since the temperature of the heat transfer medium is higher than the temperature of the circulating water, the heat transfer medium is liquefied from a gas by the action of the circulating water at a lower temperature and at the same time releases heat, thereby increasing the temperature of the circulating water. The liquid heat transfer medium is throttled by the expansion valve 34 and then returned to the evaporator 24 under pressure, and the above steps are repeated. In the cycle described above, heat transfer is achieved from

- 4 039793 spent mine air into circulating water.

As shown in FIG. 1, the air heat exchange unit 2 and the water heat exchange unit 3 form an air heat pump unit, it being understood that a person skilled in the art can install a plurality of air heat pump units according to the mine exhaust air output. In the present invention, the number of air heat exchange units 2 and water heat exchange units 3 is not specifically limited.

In this embodiment, the evaporator 24 includes at least four rows of plate sets that are stacked and corrugated.

In addition, the number of plate sets may be four rows, the first plate set 243, the second plate set 244, the third plate set 245, and the fourth plate set 246, respectively. As shown in FIG. 5A, four rows of plate sets can be arranged in an M pattern.

In addition, as shown in FIG. 5B, plate sets may be provided in a W. Of course, rows of plate sets may also be arranged in the evaporator 24 in other arrangements such as combinations of W and V, combinations of M and M, and the like.

In the highland area, the local air density is only 50-60% of the air density at sea level, and due to the arrangement of plate sets, the evaporator 24 of the air heat pump of the invention increases the heat exchange area with the exhaust mine air, ensures that the flow does not decrease, and meets the requirements of the system of recovery and utilization of waste heat in the mining area.

In addition, as shown in FIG. 4, each row of plate sets may comprise an evaporator tube 241 and a plurality of spaced plates 242. The distance between two adjacent plates 242 d may be 3-6 mm, such as 3.5 mm, 4 mm, 4.5 mm , 5 mm, 5.5 mm, etc.

In addition, the distance between two adjacent plates 242 may be 4-5 mm.

In addition, the distance between two adjacent plates 242 may be 4.2 mm.

Specifically, the distance between two adjacent plates 242 of the evaporator 24 in the prior art is 1.8 mm, and the present invention increases the distance between the plates 242 so that the effect on the heat absorption efficiency of the plates 242 due to dust in the air adhering to the surface of the plates can be reduced. 22. Meanwhile, the distance between the plates 242 is increased, and thus a sufficient space is kept for the workers to clean the plates 242 with the cleaning equipment.

In addition, the air utilizing heat pump unit includes a control unit for controlling the operation of the air utilizing heat pump unit, such as temperature control, defrost control, and the like.

In addition, the installation position of the evaporator 24 is separated from the installation positions of the compressor 25, the condenser 33 and the expansion valve 34 so that the evaporator 24 can be installed at the air outlet end of the air flow directing device according to the specific structure of the air directing device. The compressor 25, condenser 33, and expansion valve 34 are located away from the installation position of the evaporator 24, and it is not necessary to install the compressor 25, condenser 33, and expansion valve 34 at the air outlet end of the air flow directing device. Due to the structure, the installation space of the air flow guide device is saved and a sufficient installation position is reserved for the evaporator 24, meanwhile, the installation complexity of the entire equipment is reduced.

In addition, the water heat exchange unit 3 includes a water inlet 31 and a water outlet 32, a hot water supply pipe 41 is connected to the water outlet 32, and a hot water return pipe 42 is connected to the water inlet 31. The heated circulating water flows out of the water outlet 32 and flows into the hot water utilization device 5 through the hot water supply pipe 41 . The hot water recovery device 5 is, for example, an inlet mine air preheater, and after the circulating water passes through the inlet mine air preheater, the temperature of the circulating water is correspondingly lowered because the heat of the circulating water is transferred to the inlet mine air. The circulating water having a reduced temperature flows into the water inlet 31 through the hot water return pipe 42 under the action of the circulation water pump unit 43, the above heating process is repeated, and then the circulating water flows into the hot water supply pipe 41 through the water outlet 32 and etc.

In addition, as shown in FIG. 1, the air heat exchange unit 2 includes a first side surface 22 in contact with outside air and a second side surface 23 in contact with exhaust air in the air flow guide device 1. The exhaust air flows through the air duct of the air flow guide device 1 and first contacts the surface. 23 of the second side of the air heat exchange unit 2 and the exhaust air enters the air heat exchange unit 2 from the surface 23 of the second side. The exhaust air that has completed the heat transfer in the air heat exchanger unit 2 is discharged from the surface 22 of the first side.

- 5 039793 us to the outside air.

Additionally, the hot water recovery device 5 may be a mine air intake preheater, a shower device, a heating device, or other devices requiring hot water, or a combination of the above devices using hot water. In the present invention, the specific type of the hot water recovery device 5 is not limited, and for convenience of description, the hot water recovery device 5 is schematically described as an incoming mine air preheating device.

Additionally, the air flow directing device 1 includes a horizontal air duct 11 and a curved air duct 12, while the two ends of the horizontal air duct 11 are respectively connected to the exhaust mine air ventilation shaft 6 and the curved air duct 12, and the other end of the curved air duct 12 is connected to the air heat exchange unit 2. Horizontal the air duct 11 and the curved air duct 12 are located in series between the exhaust mine air ventilation shaft 6 and the air heat exchange unit 2. The horizontal air duct 11 is approximately perpendicular to the exhaust mine air ventilation shaft 6, so that after the exhaust air mine air, the air flow direction is blocked because the air flow direction of the horizontal air duct 11 is approximately perpendicular to the air flow direction of the ventilation mine 6 of the exhaust mine air and the exhaust air flow rate is further reduced. After the speed is reduced, the exhaust air enters the curved air duct 12, and the curved air duct 12 bends smoothly, so that the exhaust air becomes uniform and weak after passing through the curved air duct 12, while further securing the contact area and contact time of the air heat exchanger 2 and the exhaust air, and improving heat transfer efficiency.

Additionally, in this embodiment shown in FIG. 6, the air flow directing device 1 additionally includes a supply air pipe 13 installed at the shaft mouth 9 with an upward extension, while the supply air pipe 13 is connected to the horizontal air duct 11 and the supply air pipe 13 is hermetically connected to the shaft mouth 9 and the horizontal air duct 11.

The cross-sectional shape of the supply air pipe 13 is a shape corresponding to the shaft mouth 9, such as a circle, a rectangle, and the like. One end of the supply air pipe 13 is connected to the shaft mouth 9 in a hermetic manner, for example, an O-ring or a sealing adhesive can be placed between the supply air pipe 13 and the shaft mouth 9 so that the exhaust air enters directly into the supply air pipe 13 after it has been discharged from the shaft. mouth 9 of the mine. The mouth 9 of the mine and the pipe 13 of the supply air are sealed so as to prevent accidental leakage of the exhaust air of the mine. Similarly, the supply air pipe 13 and the air flow guide device 1 are also connected in a sealed manner, and a sealing ring or a sealing adhesive can be used.

The air flow guide device 1 is generally horizontal, one end of the air flow guide device 1 is connected to the supply air pipe 13, and the other end of the air flow guide device 1 is connected to the air heat exchange unit 2. The air flow guide device 1 of the present invention is different from the tower air flow directing device of the prior art. The air flow guiding device of the prior art has a large overall height, and it is inconvenient for workers to enter and exit for maintenance, evacuation, and the like. The air flow guide device is arranged horizontally, so that the overall height of the air flow guide device is low, and this facilitates the entry and exit of workers.

As shown in FIG. 6 and 7, the air guide device 1 is connected to the sole F via a support beam 8 and does not directly contact the sole F. Since the shaft sole F is generally uneven, if the air guide device 1 is mounted directly on the sole F, it may damage the air flow guide device 1. When using the structure connected by the support rods 8, it is possible to install the support rods 8 of different lengths to accommodate the inhomogeneities of the sole F, so that the air flow guide device 1 can be arranged horizontally.

In addition, the support rods 8 can be made of wood. During operation of the air heat exchange unit 2 at the top of the air flow guide unit 1, the air heat exchange unit 2 may vibrate, and due to the structure of the wooden support rods 8, accidental damage to the air flow guide unit 1 caused by the vibration of the air heat exchange unit 2 transmitted to the sole F is effectively mitigated.

In addition, the air flow guide device 1 further comprises a horizontal service platform 10, and the support rod 8 is located below the service platform 10, and it is connected to the sole F through the support rod 8. An operator can work on the service platform 10, for example, for maintenance , transportation and

- 6 039793

etc.

Additionally, the service platform 10 can be positioned horizontally at the bottom of the air flow guide device 1, and the plane of the service platform 10 is aligned with the upper end of the surface of the supply air pipe 13. The guard 101 is also located near the junction of the supply air pipe 13 and the service platform 10 so as to prevent an operator from accidentally falling into the shaft while working.

In addition, at least one ventilation door 14 is provided in the supply air pipe 13. In the prior art, the air flow guiding device 1 is not equipped with a ventilation door 14, and when the waste heat recovery and recovery system for exhaust air is not in operation, the exhaust air can be exhaust only through the gap of the air heat exchange unit 2. In this embodiment, at least one ventilation door 14 is designed, and in the period of no heat recovery, the ventilation door 14 is opened to discharge the exhaust mine air from the air flow directing device in a timely manner.

It should be understood that in the present invention, the specific number of ventilation doors 14 is not particularly limited, and those skilled in the art can design the number of ventilation doors 14 according to the amount of exhaust air in the mine. For ease of explanation, this embodiment schematically shows three ventilation doors 14.

Additionally, as shown in FIG. 7, the lower parts of the three ventilation doors 14 are close to the plane of the service platform 10, so that the worker can conveniently enter the air flow guide device 1 through the ventilation doors 14 from the service platform 10, or the worker can return to the service platform 10 through the ventilation doors 14 from the air guide air device 1.

Specifically, when maintenance is required, the worker enters the maintenance platform 10 and directly enters the air flow guide device 1 through the ventilation door 14. When the miners need to be evacuated, the personnel evacuation process is opposite to the maintenance process and is not described in detail.

In addition, the supply air pipe 13 is connected to the horizontal air duct 11 and the supply air pipe 13 is connected to the shaft mouth 9 and the horizontal air duct 11 in a sealed manner. At the same time, the horizontal air duct 11 is connected to the sole by means of support rods 8. The horizontal air duct 11 is perpendicular to the axis of the supply air pipe 13, so that after the exhaust mine air is discharged from the mine, the flow rate of the exhaust mine air decreases, because the direction of air flow in the horizontal air duct 11 perpendicular to the direction of air flow in the supply air pipe 13 . After the decelerated exhaust mine air enters the curved air duct 12, since the curved air duct 12 bends smoothly, the exhaust air becomes uniform and calm after passing through the curved air duct 12, which is advantageous for the waste heat recovery device to fully absorb the waste heat of the exhaust mine air.

Moreover, a guide plate 7 is also provided in the air flow guide device 1, and the guide plate 7 can be positioned in the curved air duct 12.

Additionally, the guide plate 7 may be in the form of an arch, with the concave surface of the arched guide plate 7 turned towards the exhaust mine air, and the convex surface of the arched guide plate 7 is turned away from the exhaust mine air. When the exhaust mine air contacts the guide plate 7, the concave surface of the guide plate 7 is arched, so that the exhaust mine air is damped and the exhaust mine air is more uniform and quiet. For example, the speed of the exhaust mine air in the initial state is usually 8 m/s, and the speed of the exhaust mine air can be reduced to 4 m/s or even lower by the combined action of the horizontal air duct 11, the curved air duct 12, and the guide plate 7. Therefore, the contact time of the exhaust air mine air and air heat exchanger 6 effectively increase and improve the waste heat recovery efficiency.

In addition, as shown in FIG. 1, the hot water conveying device 4 further comprises a circulating water pump assembly 43 which is used to circulate the circulating water in series between the water heat exchanger assembly 3, the hot water supply pipe 41, the hot water recovery device 5, and the hot water return pipe 42.

In addition, both sides of the circulating water pump 431 are respectively equipped with a flexible joint 434 that prevents vibration and noise generated by the circulating water pump 431 during operation from being transmitted to the hot water return pipe 42 or other mechanisms.

Additionally, the outlet end of the circulating water pump 431 is further equipped with a check valve 432 so that the circulating water can only flow in one direction and reverse flow is prevented.

Additionally, a filter 433 is further provided at the water inlet of the circulating water pump 431, and is used to filter the circulating water.

- 7 039793

It should be understood that the circulating water pump assemblies 43 may be provided in a plurality of sets, and in this embodiment, the circulating water pump assemblies 43 are provided in three sets. During operation, two sets of circulating water pump units are used.

43, another set of circulating water pump assemblies 43 is ready for use.

In addition, the hot water conveying device 4 further comprises an auxiliary water supply device for supplying circulating water. The booster water device includes a booster pump 44, a flexible connection 434, and a check valve 432, and the working principle of the booster water supply device is similar to that of the circulating water pump unit 43, and is again not described in detail.

Moreover, the hot water conveying device 4 also includes a water softening device 45 that can be connected directly to tap water. The water softening device includes a water softener tank 451 and a brine tank 452, where the water softener tank 451 is used to remove calcium and magnesium ions in tap water to soften the water. The brine tank 452 may allow brine to pass through the water softener tank 451 to restore the softening exchange function of the water softener tank 451. Specifically, tap water first enters the water softener tank 451, and then calcium and magnesium ions are replaced from the tap water by the water softener tank 451. When the water softener tank 451 absorbs a certain amount of calcium and magnesium ions, the calcium and magnesium ion removal efficiency of the resin gradually decreases, so that regeneration is required. The regeneration method is to use the brine from the brine tank 452 to pass through the resin to replace the calcium and magnesium ions on the resin, and to discharge the calcium and magnesium ions from the water softener tank 451, so that the softening exchange function returns to the resin.

In addition, the waste heat recovery and recovery system for the mine exhaust air further includes an automatic control system used to control the operating conditions of the waste heat recovery and recovery system for the exhaust mine air.

In conclusion, the advantages and beneficial effects of the present invention are as follows.

Through the use of air heat pump technology, the exhaust mine air is in direct contact with the air heat exchanger, heat is transferred from the exhaust air to the air heat exchanger, and then the heat of the exhaust air is transferred to the water circulating through the water heat exchanger. Compared with the prior art, the structure of the water spraying device and the water collection tank are omitted, so that the structure of the recovery system is simplified.

In addition, in the present invention, heat can be transferred from the mine exhaust air to the circulating water only by an air heat pump, and compared to the prior art in which heat is first supplied by atomized water and then transferred to the circulating water by heat utilizing water. heat pump, the system according to the invention has a greatly improved heat recovery coefficient of the exhaust mine air.

It should be understood that the invention is not limited in its application to the details of the design and layout of the components set forth in the technical description. Other embodiments are possible for the invention and are practiced and carried out in various ways. Changes and modifications to the foregoing are within the scope of the present invention. It should be understood that the invention described and defined in this technical specification extends to all alternative combinations of two or more of the individual features mentioned or evident from the text and/or drawings. All of these various combinations constitute various alternative aspects of the present invention. The embodiments described in this technical description show the best manner known for the practice of the invention and provide for the use of the invention by a person skilled in the art.

CLAIM

Claims (9)

CLAIM 1. Waste heat recovery and utilization system for exhaust mine air, comprising an air flow guiding device, an air heat exchange unit, a water heat exchange unit, a hot water transportation device and a hot water recovery device, one end of the air duct of the air flow guiding device is connected to the ventilation shaft of the spent mine air, and the other end of the air duct is connected to the air heat exchange unit, while the air flow guiding device contains a horizontal guiding air duct and a curved guiding air duct, with two ends of the horizontal guiding air duct being respectively connected to the exhaust mine air ventilation shaft and a curved guiding air duct, and the other end of the curved guide air duct is connected to the air heat exchange unit; the air flow directing device additionally comprises a supply air pipe, which is installed at the mouth of the exhaust mine air ventilation shaft with upward expansion, the supply air pipe is connected to the horizontal guide air duct, and the supply air pipe is hermetically connected to the inlet of the exhaust mine air ventilation shaft and a horizontal guide air duct, where the horizontal guide air duct is connected to the bottom of the shaft by means of support rods and the horizontal guide air duct is perpendicular to the axis of the supply air pipe, the hot water conveying device comprises a hot water supply pipe and a hot water return pipe, wherein one end of the hot water supply pipe and one end of the hot water return pipe is connected to the water heat exchanger, and the other end of the hot water supply pipe and the other end of the hot water return pipe are connected to the hot water recovery device. cells of water, the air heat exchange unit is connected to the water heat exchange unit via a refrigerant pipeline, and the air heat exchange unit is configured to absorb the heat of the exhaust air, and the water heat exchange unit is configured to conduct the heat absorbed by the air heat exchange unit into the water circulating in the hot water transport device. water. 2. The waste heat recovery and utilization system for exhaust mine air according to claim 1, in which the air heat exchange unit contains an evaporator, a compressor connected to the evaporator, and the water heat exchange unit contains an expansion valve, a condenser, where the expansion valve, evaporator, compressor and condenser connected in series one after the other. 3. The waste heat recovery and recovery system for exhaust mine air according to claim 1, wherein the evaporator comprises at least four rows of plate sets, and the at least four rows of plate sets are stacked and corrugated. 4. The waste heat recovery and utilization system for exhaust mine air according to claim 3, wherein the number of plate sets comprises four rows, and these four rows of plate sets are shaped like an M or a W. 5. Waste heat recovery and utilization system for exhaust mine air according to claim 3, in which each set of plates contains a plurality of plates arranged at intervals, and the distance between two adjacent plates is 3-6 mm, preferably the distance between two adjacent plates is 4 -5 mm, most preferably the distance between two adjacent plates is 4.2 mm. 6. Waste heat recovery and utilization system for exhaust mine air according to claim 1, in which the water heat exchange unit contains a water inlet and a water outlet, and the hot water supply pipe is connected to the water outlet and the hot water return pipe is connected to the water inlet. water; the air heat exchange unit comprises a first side surface and a second side surface, the first side surface being in contact with outside air and the second side surface being in contact with exhaust air in the air flow guide device; the hot water recovery device is at least one of a mine inlet air preheater, a shower device, and a heating device. 7. The system for recovery and utilization of waste heat for exhaust mine air according to claim 1, in which the air flow guide device further comprises a horizontal service platform, and the service platform is connected to the sole by means of support rods; at the same time, at least one ventilation door is additionally located on the air flow guiding device; the surface of the upper end of the supply air pipe coincides with the plane of the service platform. 8. Waste heat recovery and utilization system for exhaust mine air according to claim 1 or 7, in which the guide plate, which is in the form of an arch, is additionally located in the air flow guiding device, and the concave surface of the guide plate is turned towards the exhaust mine air, and it is used for directing the spent mine air to the outlet. 9. The system of recovery and disposal of waste heat for exhaust mine air according to any one of paragraphs. 1 to 4, wherein the hot water conveying device further comprises a circulating water pumping unit used for sequentially circulating water between the water heat exchanger assembly, the hot water supply pipe, the hot water recovery device, and the hot water return pipe; a check valve is located at the end of the water outlet of the circulating water pump unit; wherein the hot water conveying device further comprises an additional water supply device for supplying circulating water and a water softening device for reducing the hardness of tap water.