CN220397252U - Cold energy recycling system of inflation station - Google Patents

Abstract

The utility model discloses a cold energy recycling system of an inflation station, which comprises the following components: an inflation system, a cold energy recovery system and a cold energy utilization system. The inflation system comprises a liquid storage tank, a low-temperature liquid pump, an air-to-air gasifier and an inflation device which are connected in sequence through pipelines; the cold energy recovery system comprises a first water storage tank, a first water pump, a spraying device, a collecting disc and a second water storage tank, wherein the first water storage tank, the first water pump and the spraying device are sequentially connected through pipelines, the spraying device is positioned above the air-temperature gasifier, the collecting disc is arranged below the air-temperature gasifier, a water outlet of the collecting disc, the second water pump and the second water storage tank are sequentially communicated, and the second water storage tank is a heat preservation water storage tank; the cold energy utilization system comprises a third water pump, a first heat exchanger, a first fan and a room. The system for recycling the cold energy of the charging station can recycle the cold energy formed at the air-temperature gasifier, and utilize the recycled cold energy to refrigerate a room, thereby saving energy.

Description

Cold energy recycling system of inflation station

Technical Field

The utility model relates to the technical field of inflation stations, in particular to a refrigeration capacity recycling system of an inflation station.

Background

In the charging station, it is necessary to gasify liquid gas such as liquid oxygen, argon or nitrogen by an air-temperature gasifier and then charge the gasified gas into a gas cylinder. In the traditional inflation process of the inflation station, the cold energy formed at the air-temperature gasifier is directly released into the air, so that the cold energy is wasted.

Disclosure of Invention

The present utility model aims to solve at least one of the technical problems existing in the prior art. Therefore, the utility model provides a cold energy recycling system of an air charging station, which can recycle cold energy formed at an air-conditioning gasifier, and utilize the recycled cold energy to refrigerate a room, thereby saving energy.

According to an embodiment of the utility model, a system for recycling cold energy of an air charging station comprises: an inflation system, a cold energy recovery system and a cold energy utilization system. The inflation system comprises a liquid storage tank, a low-temperature liquid pump, an air-temperature gasifier and an inflation device which are sequentially connected through pipelines, wherein the liquid storage tank is used for storing liquid gas, and the inflation device is used for inflating an air bottle; the cold energy recovery system comprises a first water storage tank, a first water pump, a spraying device, a collecting disc and a second water storage tank, wherein the first water storage tank, the first water pump and the spraying device are sequentially connected through pipelines, the spraying device is positioned above the air-temperature gasifier, the collecting disc is arranged below the air-temperature gasifier, the spraying device is used for spraying heat exchange water to the air-temperature gasifier, the collecting disc is used for collecting heat exchange water, a water outlet of the collecting disc, the second water pump and the second water storage tank are sequentially communicated, and the second water storage tank is a heat preservation water storage tank; the cold energy utilization system comprises a third water pump, a first heat exchanger, a first fan and a room, wherein the water outlet of the second water storage tank, the third water pump, the water inlet of the first heat exchanger, the water outlet of the first heat exchanger and the first water storage tank are sequentially communicated, and the air outlet of the first heat exchanger, the first fan, the room and the air inlet of the first heat exchanger are sequentially communicated.

The gas station filling system with temperature control according to the embodiment of the utility model has at least the following beneficial effects: in the working process, the first water storage tank provides heat exchange water for the spraying device, the spraying device sprays the heat exchange water to the air-temperature vaporizer, the heat exchange water can exchange heat with liquid gas through the air-temperature vaporizer, then the liquid gas is vaporized, the chilled heat exchange water is collected by the collecting tray and then enters the second water storage tank for heat preservation and storage, when a room needs to be refrigerated, the heat exchange water provided by the second water storage tank returns to the first water storage tank after cold energy is released by the first heat exchanger to form heat exchange water circulation, and the first fan enables air in the room to return to the room after passing through the first heat exchanger and absorbing the cold energy for refrigeration, so that the room refrigeration is realized.

According to some embodiments of the utility model, the cold recovery system further comprises a return pipe, one end of the return pipe is communicated with the upper part of the second water storage tank, the other end of the return pipe is communicated with the lower part of the first water storage tank, and the height position of the lower part of the first water storage tank is lower than that of the upper part of the second water storage tank.

According to some embodiments of the utility model, the room is provided with a first temperature sensor, and the first temperature sensor, the first fan and the third water pump are all electrically connected with the control device.

According to some embodiments of the utility model, the room is provided with an air conditioner, the lower part of the second water storage tank is provided with a water level sensor, and the air conditioner and the water level sensor are electrically connected with a control device.

According to some embodiments of the utility model, a first air dehumidifier is disposed between the first fan and the room.

According to some embodiments of the utility model, the air pump further comprises an air charging bin provided with a door, a second heat exchanger, a second fan and a fourth water pump, wherein an accommodating space is arranged in the air charging bin, an electronic scale for accommodating an air bottle is arranged in the accommodating space, the air charging device is positioned in the accommodating space, the water outlet of the second water storage tank, the fourth water pump, the water inlet of the second heat exchanger, the water outlet of the second heat exchanger and the first water storage tank are sequentially communicated, and the air outlet of the second heat exchanger, the first fan, the air charging bin and the air inlet of the second heat exchanger are sequentially communicated.

According to some embodiments of the utility model, the air charging device further comprises a control device, a second temperature sensor is arranged in the air charging bin and used for detecting the air temperature of the accommodating space, and the second temperature sensor, the fourth water pump and the second fan are all electrically connected with the control device.

According to some embodiments of the utility model, a second air dehumidifier is disposed between the second fan and the plenum.

According to some embodiments of the utility model, the utility model further comprises a control device, an electric heater is arranged on the pipeline between the first water pump and the spraying device, a third temperature sensor is arranged between the air-temperature gasifier and the air charging device, and the first water pump, the electric heater and the third temperature sensor are all electrically connected with the control device.

According to some embodiments of the utility model, a fourth temperature sensor is provided between the air-temperature gasifier and the inflator, the fourth temperature sensor being for measuring the temperature of the gas after passing through the air-temperature gasifier.

Additional aspects and advantages of the utility model will be set forth in part in the description which follows, and in part will be obvious from the description, or may be learned by practice of the utility model.

Drawings

The foregoing and/or additional aspects and advantages of the utility model will become apparent and may be better understood from the following description of embodiments taken in conjunction with the accompanying drawings in which:

FIG. 1 is a schematic diagram of a system for recycling cold energy of an air charging station according to an embodiment of the present utility model.

Reference numerals:

the liquid storage tank 110, the cryogenic liquid pump 120, the air-temperature vaporizer 130, the inflator 140, the first water storage tank 210, the first water pump 220, the spraying device 230, the collection tray 240, the second water storage tank 250, the second water pump 260, the return pipe 270, the electric heater 280, the third water pump 310, the first heat exchanger 320, the first fan 330, the room 340, the first air dehumidifier 350, the inflating cabin 410, the accommodating space 411, the second heat exchanger 420, the second fan 430, the fourth water pump 440, the second air dehumidifier 450, the electronic scale 460, the first temperature sensor 510, the second temperature sensor 520, the third temperature sensor 530, the fourth temperature sensor 540, the water level sensor 550, the gas cylinder 600.

Detailed Description

Embodiments of the present utility model are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative only and are not to be construed as limiting the utility model.

In the description of the present utility model, it should be understood that references to orientation descriptions such as upper, lower, front, rear, left, right, etc. are based on the orientation or positional relationship shown in the drawings, are merely for convenience of description of the present utility model and to simplify the description, and do not indicate or imply that the apparatus or elements referred to must have a particular orientation, be constructed and operated in a particular orientation, and thus should not be construed as limiting the present utility model.

In the description of the present utility model, a number means one or more, a number means two or more, and greater than, less than, exceeding, etc. are understood to not include the present number, and above, below, within, etc. are understood to include the present number. The description of the first and second is for the purpose of distinguishing between technical features only and should not be construed as indicating or implying relative importance or implicitly indicating the number of technical features indicated or implicitly indicating the precedence of the technical features indicated.

In the description of the present utility model, unless explicitly defined otherwise, terms such as arrangement, installation, connection, etc. should be construed broadly and the specific meaning of the terms in the present utility model can be reasonably determined by a person skilled in the art in combination with the specific contents of the technical scheme.

Referring to fig. 1, a system for recycling cold energy of an air charging station according to an embodiment of the present utility model includes: an inflation system, a cold energy recovery system and a cold energy utilization system. The inflation system comprises a liquid storage tank 110, a low-temperature liquid pump 120, an air-temperature gasifier 130 and an inflation device 140 which are sequentially connected through pipelines, wherein the liquid storage tank 110 is used for storing liquid gas, and the inflation device 140 is used for inflating the gas cylinder 600; the cold energy recovery system comprises a first water storage tank 210, a first water pump 220, a spraying device 230, a collecting disc 240 and a second water storage tank 250, wherein the first water storage tank 210, the first water pump 220 and the spraying device 230 are sequentially connected through pipelines, the spraying device 230 is positioned above the air gasifier 130, the collecting disc 240 is arranged below the air gasifier 130, the spraying device 230 is used for spraying heat exchange water to the air gasifier 130, the collecting disc 240 is used for collecting heat exchange water, a water outlet of the collecting disc 240 is communicated with the second water storage tank 250, and the second water storage tank 250 is a heat preservation water storage tank; the cold energy utilization system comprises a third water pump 310, a first heat exchanger 320, a first fan 330 and a room 340, wherein the water outlet of the second water storage tank 250, the third water pump 310, the water inlet of the first heat exchanger 320, the water outlet of the first heat exchanger 320 and the first water storage tank 210 are sequentially communicated, and the air outlet of the first heat exchanger 320, the first fan 330, the room 340 and the air inlet of the first heat exchanger 320 are sequentially communicated.

In the process of inflating the gas cylinder 600, the first water storage tank 210 provides heat exchange water to the spraying device 230, the spraying device 230 sprays the heat exchange water to the air-temperature vaporizer 130, the heat exchange water can exchange heat with liquid gas through the air-temperature vaporizer, then the liquid gas is gasified, and the heat exchange water absorbs cold energy and then is collected by the collecting disc 240 and enters the second water storage tank 250 for heat preservation and storage; when the room 340 needs to be refrigerated, the heat exchange water provided by the second water storage tank 250 returns to the first water storage tank 210 after the cold energy is released by the first heat exchanger 320, so that heat exchange water circulation is formed, the first fan 330 enables the air in the room 340 to pass through the first heat exchanger 320 and absorb the cold energy to be refrigerated and then return to the room 340, and the room 340 is refrigerated.

By spraying heat exchange water to the air-temperature gasifier 130, the heat exchange water can absorb heat in air and exchange heat with liquid gas in the air-temperature gasifier 130, so that heat exchange can be performed by using air and heat exchange water at the same time, heat exchange efficiency is improved, and gasification of the liquid gas can be more complete.

Wherein, through setting up first water storage tank 210 and second water storage tank 250, store the heat exchange water that the temperature is higher and absorbed the lower heat exchange water of temperature behind the cold volume respectively, compare with the mode that only uses a water storage tank, can avoid the heat exchange water of different temperatures to mix together, influence and refrigerate for room 340, simultaneously, first water storage tank 210 can not be too low for the heat exchange water temperature that spray set 230 provided, avoid influencing the gasification effect of air-condition gasifier 130.

In a specific implementation process, the room 340 does not need to be refrigerated during the inflation process, and at this time, the situations that the liquid level of the first water storage tank 210 is too low and the liquid level of the second water storage tank 250 is too high may occur, so that in order to avoid the water shortage of the first water storage tank 210, the second water pump 260 may be selectively started to pump the heat exchange water in the second water storage tank 250 into the first water storage tank 210.

In the specific implementation process, when the air inflation is not performed and the room 340 needs to be refrigerated, the refrigeration can be performed by utilizing the cooling capacity of the heat exchange water in the second water storage tank 250, the air inflation and the refrigeration of the room 340 can be performed respectively, and the stability of the system is improved.

In the specific implementation process, the heat exchange water is water added with substances such as antifreeze or salt capable of reducing the freezing point of the water, so that the freezing point of the heat exchange water is smaller than zero, and the phenomenon that the heat exchange water is frozen in the circulation process is effectively avoided.

In the specific implementation, referring to fig. 1, it is conceivable that the cold recovery system further includes a return pipe 270, one end of the return pipe 270 is connected to the upper portion of the second water storage tank 250, and the other end of the return pipe 270 is connected to the lower portion of the first water storage tank 210, and the lower portion of the first water storage tank 210 is located at a lower height than the upper portion of the second water storage tank 250. Thus, when the heat exchange water in the second water storage tank 250 is at a high liquid level, the heat exchange water in the second water storage tank 250 can automatically flow back into the first water storage tank 210, so that the water shortage of the first water storage tank 210 is avoided.

Referring to fig. 1, it is envisioned that in some embodiments, a control device is further included, and a first temperature sensor 510 is disposed within the room 340, and the first temperature sensor 510, the first fan 330, and the third water pump 310 are all electrically connected to the control device. When the temperature value measured by the first temperature sensor 510 is smaller than the required room 340 temperature, the control device can control the first fan 330 and the third water pump 310 to stop running, so that the room 340 is prevented from being excessively low due to continuous refrigeration, and when the temperature value measured by the first temperature sensor 510 is larger than the required room 340 temperature, the control device can control the first fan 330 and the third water pump 310 to run, so that the room 340 is refrigerated, and through the arrangement, the running of the refrigerating capacity utilization system can be automatically controlled, and the temperature in the room 340 is kept within a certain range.

In the specific implementation process, the room 340 may be a factory building, an office, or the like, where refrigeration is required.

Referring to fig. 1, it is conceivable that in some embodiments, when the room 340 is a factory building, an office, or the like, the room 340 may be further provided with an air conditioner, and the lower portion of the second water storage tank 250 is provided with a water level sensor 550, and the air conditioner and the water level sensor 550 are electrically connected to the control device. In a specific implementation process, the second water tank 250 may lack the heat exchange water absorbing the cold energy because the air charging operation is not performed for a long time, and thus, the control device may control the air conditioner to operate when the water level sensor 550 senses that the second water tank 250 lacks water. The air conditioner is complementary with the cold energy utilization system, and compared with the air conditioner which is independently used, the energy consumption can be reduced, and the operation cost of manufacturers can be reduced.

Referring to fig. 1, it is conceivable that in some embodiments, a first air dehumidifier 350 is provided between the first fan 330 and the room 340, and the moisture content of the air entering the first heat exchanger 320 is reduced by the first air dehumidifier 350, so that frosting of the first heat exchanger 320 is reduced.

During inflation at the inflation station, when gas is inflated into the gas cylinder 600, the temperature of the gas cylinder 600 increases, and if the temperature of the gas cylinder 600 is too high, a risk of explosion may occur.

Referring to fig. 1, it is conceivable that in some embodiments, the air pump further comprises an air charging bin 410 provided with a door, a second heat exchanger 420, a second fan 430 and a fourth water pump 440, wherein an accommodating space 411 is arranged in the air charging bin 410, an electronic scale 460 for accommodating the air bottle 600 is arranged in the accommodating space 411, the air charging device 140 is positioned in the accommodating space 411, the water outlet of the second water storage tank 250, the fourth water pump 440, the water inlet of the second heat exchanger 420, the water outlet of the second heat exchanger 420 and the first water storage tank 210 are sequentially communicated, and the air outlet of the second heat exchanger 420, the first fan 330, the air charging bin 410 and the air inlet of the second heat exchanger 420 are sequentially communicated. When the air bottle 600 is inflated in the accommodating space 411, the air bottle 600 is placed on the electronic scale 460, so that the air can be inflated while the mass of the inflated air is measured, in the process, the heat exchange water in the second water storage tank 250 can be utilized to produce cold air, and the cold air is sent into the inflation bin 410 to cool the air bottle 600, so that the temperature of the air bottle 600 is prevented from being increased, and the risk of explosion of the air bottle 600 is reduced.

Referring to fig. 1, it is conceivable that in some embodiments, a second temperature sensor 520 is disposed in the inflating compartment 410, the second temperature sensor 520 is configured to detect the air temperature of the accommodating space 411, and the second temperature sensor 520, the fourth water pump 440, and the second fan 430 are all electrically connected to the control device. When the temperature value measured by the second temperature sensor 520 is smaller than the temperature required by the accommodating space 411, the control device can control the second fan 430 and the fourth water pump 440 to stop running, so that the temperature of the inflating cabin 410 is prevented from being too low due to continuous refrigeration, and the danger caused by too large temperature difference between the outer wall and the inner wall of the gas cylinder 600 is avoided; when the temperature value measured by the second temperature sensor 520 is greater than the temperature required by the accommodating space 411, the control device can control the second fan 430 and the fourth water pump 440 to operate, so as to avoid the effect of the temperature rise of the accommodating space 411 affecting the cooling air bottle 600.

Referring to fig. 1, it is envisioned that in some embodiments, a second air dehumidifier 450 is disposed between the second blower 430 and the plenum 410. The water content in the air entering the second heat exchanger 420 is reduced by the second air dehumidifier 450, and the frosting of the second heat exchanger 420 is reduced.

Referring to fig. 1, it is conceivable that in some embodiments, an electric heater 280 is disposed on a pipeline between the first water pump 220 and the spraying device 230, a third temperature sensor 530 is disposed between the air temperature gasifier 130 and the inflator 140, and the first water pump 220, the electric heater 280, and the third temperature sensor 530 are all electrically connected to the control device. When the outside air temperature is low or the temperature of the heat exchange water provided from the first water storage tank 210 is low, the heat exchange efficiency of the air-temperature vaporizer 130 is lowered, which may cause the liquid gas to be not vaporized effectively, affecting the inflation of the gas cylinder 600. At this time, the temperature of the heat exchange water sprayed from the spraying device 230 can be increased by the electric heater 280, so that the air-temperature gasifier 130 can gasify the liquid gas effectively. A fourth temperature sensor 540 is disposed between the air-temperature vaporizer 130 and the inflator 140, the fourth temperature sensor 540 is used for measuring the temperature of the gas passing through the air-temperature vaporizer 130, and if the gas temperature is low, for example, less than zero degrees, it indicates that the vaporization of the liquid gas is incomplete, and the control device can control the electric heater 280 to work.

The technical features of the above-described embodiments may be arbitrarily combined, and all possible combinations of the technical features in the above-described embodiments are not described for brevity of description, however, as long as there is no contradiction between the combinations of the technical features, they should be considered as the scope of the description.

The present embodiment has been described in detail with reference to the drawings, but the present utility model is not limited to the above embodiment, and various changes can be made within the knowledge of those skilled in the art without departing from the spirit.

Claims (10)

1. The cold energy recycling system of gas station, its characterized in that includes:

the inflation system comprises a liquid storage tank (110), a low-temperature liquid pump (120), an air-temperature gasifier (130) and an inflation device (140) which are sequentially connected through pipelines, wherein the liquid storage tank (110) is used for storing liquid gas, and the inflation device (140) is used for inflating a gas cylinder (600);

the cold energy recovery system comprises a first water storage tank (210), a first water pump (220), a spraying device (230), a collecting disc (240), a second water pump (260) and a second water storage tank (250), wherein the first water storage tank (210), the first water pump (220) and the spraying device (230) are sequentially connected through pipelines, the spraying device (230) is positioned above the air-temperature gasifier (130), the collecting disc (240) is arranged below the air-temperature gasifier (130), the spraying device (230) is used for spraying heat exchange water to the air-temperature gasifier (130), the collecting disc (240) is used for collecting heat exchange water, a water outlet of the collecting disc (240), the second water pump (260) and the second water storage tank (250) are sequentially communicated, and the second water storage tank (250) is a heat preservation water storage tank.

The cold energy utilization system comprises a third water pump (310), a first heat exchanger (320), a first fan (330) and a room (340), wherein a water outlet of a second water storage tank (250), the third water pump (310), a water inlet of the first heat exchanger (320), a water outlet of the first heat exchanger (320) and the first water storage tank (210) are sequentially communicated, and a gas outlet of the first heat exchanger (320), the first fan (330), the room (340) and a gas inlet of the first heat exchanger (320) are sequentially communicated.

2. The charge air station cold recycling system according to claim 1, further comprising a return pipe (270), one end of the return pipe (270) is communicated with an upper portion of the second water storage tank (250), the other end of the return pipe (270) is communicated with a lower portion of the first water storage tank (210), and a lower portion height position of the first water storage tank (210) is lower than a height position of an upper portion of the second water storage tank (250).

3. The system of claim 1, further comprising a control device, wherein a first temperature sensor (510) is disposed in the room (340), and the first temperature sensor (510), the first fan (330), and the third water pump (310) are all electrically connected to the control device.

4. A system for recycling cold energy of a gas station according to claim 3, characterized in that the room (340) is provided with an air conditioner, a water level sensor (550) is provided at the lower part of the second water storage tank (250), and the air conditioner and the water level sensor (550) are electrically connected with a control device.

5. The air charging station cold recycling system according to claim 1, characterized in that a first air dehumidifier (350) is provided between the first fan (330) and the room (340).

6. The system for recycling cold energy of an air charging station according to claim 1, further comprising an air charging bin (410) provided with a door, a second heat exchanger (420), a second fan (430) and a fourth water pump (440), wherein an accommodating space (411) is arranged in the air charging bin (410), an electronic scale (460) for placing an air bottle (600) is arranged in the accommodating space (411), the air charging device (140) is positioned in the accommodating space (411), a water outlet of the second water storage tank (250), the fourth water pump (440), a water inlet of the second heat exchanger (420), a water outlet of the second heat exchanger (420) and the first water storage tank (210) are sequentially communicated, and an air outlet of the second heat exchanger (420), the first fan (330), the air charging bin (410) and an air inlet of the second heat exchanger (420) are sequentially communicated.

7. The system for recycling cold energy of an air charging station according to claim 6, further comprising a control device, wherein a second temperature sensor (520) is arranged in the air charging bin (410), the second temperature sensor (520) is used for detecting the air temperature of the accommodating space (411), and the second temperature sensor (520), the fourth water pump (440) and the second fan (430) are all electrically connected with the control device.

8. The system of claim 6, wherein a second air dehumidifier (450) is disposed between the second fan (430) and the aeration bin (410).

9. The system for recycling cold energy of an air charging station according to claim 1, further comprising a control device, wherein an electric heater (280) is arranged on a pipeline between the first water pump (220) and the spraying device (230), a third temperature sensor (530) is arranged between the electric heater (280) and the spraying device (230), and the first water pump (220), the electric heater (280) and the third temperature sensor (530) are all electrically connected with the control device.

10. The system according to claim 9, characterized in that a fourth temperature sensor (540) is arranged between the air-temperature gasifier (130) and the inflator (140), the fourth temperature sensor (540) being used for measuring the temperature of the gas after passing through the air-temperature gasifier (130).