CN205137767U - Multi -functional cold storage air conditioner - Google Patents

Abstract

The utility model provides a multi -functional cold storage air conditioner, includes that compressed air produces device, refrigerating plant, cold -storage device and arranges the cold charge and put, compressed air produce the device pass through the compressed air pipe with cold -storage device intercommunication, the intercommunication is put with arranging the cold charge to the cold -storage device, and refrigerating plant's refrigeration portion cover is established and is equipped with a heat reclamation device at the compressed air pipe outside, radiating part outside cover, lies in refrigerating plant and compressed air and produces the compressed air pipe outside between the device and overlap and be equipped with the 2nd heat reclamation device. The utility model discloses thereby make when the power consumption ebb to produce the high temperature compressed air's that the device produced heat through compressed air and can be be in proper order absorbed by the 2nd heat reclamation device, refrigerating plant and use when storing in order to the power consumption peak in forming microthermal compressed air and getting into the cold -storage device, and the absorbed heat can also be retrieved with the 2nd heat reclamation device by a heat reclamation device and recycle, not only improve the effect that compressed air lowers the temperature evidently, the waste of the energy that has significantly reduced in addition.

Description

A kind of multi-functional cooling storage air conditioning system

Technical field

The utility model relates to a kind of air-conditioning, refers in particular to a kind of multi-functional cooling storage air conditioning system.

Background technology

Nowadays the electricity charge grow to even greater heights, therefore due to the enforcement of electricity consumption high ebb electrovalence policy makes the electricity charge of user when peak of power consumption needed for electricity consumption will far above the electricity charge needed for during electricity consumption ebb.

The period of peak of power consumption is general by day, the period of electricity consumption ebb is generally at night, but people to work and rest normally be all that the power consumption such as to go to school daytime is large, night's rest power consumption is little, the electricity charge that particularly daytime, using air-condition produced will far above evening, the amount of money so making the required payment of people's normal electricity consumption also the just and then electricity charge raising and when the river rises the boat goes up.

Although nowadays also have at electricity consumption ebb storing compressed air, compressed-air actuated equipment is discharged when peak of power consumption, but the compressed air of storage can not be effectively utilized very much, because compressed-air actuated high heat makes compressed air can not play good cooling-down effect when discharging, and heat cannot effectively be reclaimed, thus cause a large amount of wastes.

Utility model content

The utility model provides a kind of multi-functional cooling storage air conditioning system, and its main purpose is that overcoming existing equipment can not play good cooling-down effect when discharging compressed air, and heat cannot effectively be reclaimed, thus causes the defect of a large amount of wastes.

For solving the problems of the technologies described above, the utility model adopts following technical scheme:

A kind of multi-functional cooling storage air conditioning system, the row's device for cooling comprising compressed air generator, refrigerating plant, cold-storage device and the cold air in cold-storage device is discharged, described compressed air generator is communicated with described cold-storage device by air-pressure duct, described cold-storage device is communicated with described row's device for cooling, the refrigeration section of described refrigerating plant is set in outside described air-pressure duct, outside radiating part and is arranged with the first heat reclamation device, is arranged with the second heat reclamation device outside the air-pressure duct between described refrigerating plant and compressed air generator.

Further, described first heat reclamation device offers near described radiating part and the side of refrigeration section junction and is connected the first outside delivery port, side away from described radiating part and refrigeration section junction offers the first water inlet, the radiating part of described refrigerating plant is equiped with the first temperature sensor, described first delivery port is equiped with the second temperature sensor and for comparing the first temperature sensor and the second temperature sensor to control the first governor motion of drainage rates, described first governor motion respectively with described first temperature sensor, second temperature sensor signal connects.

Further, described first governor motion comprises for the first intelligent temperature comparator of more described first temperature sensor and the second temperature sensor temperature difference and for regulating the first flow regulator of drainage rates, and described first intelligent temperature comparator is connected with described first flow regulator signal.

Further, described second heat reclamation device offers near the side of described compressed air generator and connects the second outside delivery port, the second water inlet is offered near the side of described refrigerating plant, the air-pressure duct being positioned at described second heat reclamation device is equiped with three-temperature sensor, described second delivery port is equiped with the 4th temperature sensor and for comparing three-temperature sensor and the 4th temperature sensor to control the second governor motion of drainage rates, described second governor motion respectively with described three-temperature sensor, 4th temperature sensor signal connects.

Further, described second governor motion comprises for the second intelligent temperature comparator of more described three-temperature sensor and the 4th temperature sensor temperature difference and for regulating the second flow regulator of drainage rates, and described second intelligent temperature comparator is connected with described second flow regulator signal.

Further, described second heat reclamation device comprises a water tank and a draining pump, described water tank is connected with described draining pump by a drainpipe, described drainpipe is set in outside described air-pressure duct, described second delivery port is opened on described water tank, and described second water inlet is opened on described draining pump.

Further, described compressed air generator comprises an air compressor and an air cleaning unit, and described air cleaning unit one end is communicated with described air compressor, the other end is communicated with described air-pressure duct.

Further, described air cleaning unit comprises a PM2.5 clarifier and an anion generator be communicated with this PM2.5 clarifier.

Further, described cold-storage device is a compressed air air reservoir, described row's device for cooling is communicated with by exhaust manifolds with described compressed air air reservoir, one the 5th temperature sensor is equiped with outside described row's device for cooling, one the 6th temperature sensor is equiped with in described compressed air air reservoir, be equiped with one in described exhaust manifolds for comparing the 5th temperature sensor and the 6th temperature sensor to control the 3rd governor motion of deflation rate, described 3rd governor motion is connected with described 5th temperature sensor, the 6th temperature sensor signal respectively.

Further, described 3rd governor motion comprises for the 3rd intelligent temperature comparator of more described 5th temperature sensor and the 6th temperature sensor temperature difference and for regulating the air damper of deflation rate, and described 3rd intelligent temperature comparator is connected with described air damper signal.

Compared to the prior art, the beneficial effect that the utility model produces is:

1, the utility model structure is simple, practical, by arranging refrigerating plant, first heat reclamation device and the second heat reclamation device, make the heat of the high temperature compressed air produced by compressed air generator when electricity consumption ebb can successively by the second heat reclamation device, refrigerating plant absorbs thus forms the compressed air of low temperature and enter in cold-storage device to store and use in order to during peak of power consumption, and absorbed heat can also by the first heat reclamation device and the second heat reclamation device recycling, not only significantly enhance the effect of compressed air cooling, and greatly reduce the waste of the energy.

2, the utility model is by arranging the first temperature sensor, the second temperature sensor and the first governor motion, make the first governor motion automatically can compare the temperature difference of refrigerating plant radiating part and the first delivery port, thus adjust drainage rates in real time according to temperature difference size.When the temperature difference is large, drainage rates is low; When having a narrow range of temperature, drainage rates is high.Just the coolant-temperature gage of discharging that can make like this can not be too low, and impact uses, and the coolant-temperature gage in the first heat reclamation device also can not be made too high, cause energy dissipation.Simultaneously due to the effect of heat trnasfer, the water temperature of close radiating part and side, refrigeration section junction will be significantly higher than the water temperature away from radiating part and side, refrigeration section junction, first delivery port is arranged on and the coolant-temperature gage of discharging can also be made to be the highest in the first heat reclamation device all the time near the side of radiating part and refrigeration section junction, improve the rate of recovery of heat further.

3, the utility model by arranging the second heat reclamation device between compressed air generator and refrigerating plant, make compressed air before the refrigeration section entering refrigerating plant is freezed, first can carry out preliminary recuperation of heat by the second heat reclamation device, so just can reduce the energy that refrigeration section consumes for refrigeration.

4, the utility model is by arranging three-temperature sensor, the 4th temperature sensor and the second governor motion, make the second governor motion automatically can compare the temperature difference being positioned at the second heat reclamation device compressed air conduit and the second delivery port, thus adjust drainage rates in real time according to temperature difference size.When the temperature difference is large, drainage rates is low; When having a narrow range of temperature, drainage rates is high.Just the coolant-temperature gage of discharging that can make like this can not be too low, and impact uses, and the coolant-temperature gage in the second heat reclamation device also can not be made too high, cause energy dissipation.Simultaneously due to the effect of heat trnasfer, water temperature near compressed air generator side will be significantly higher than the water temperature near refrigerating plant side, second delivery port being arranged on the coolant-temperature gage that can also make discharge near compressed air generator side is the highest in the second heat reclamation device all the time, improves the rate of recovery of heat further.

5, in the utility model, by a drainpipe sheathed outside air-pressure duct, make the water in draining pump will must first through drainpipe when water tank is discharged, and due to water in drainpipe in the unit interval by amount little, therefore can obtain the transmission of air-pressure duct compressed air heat through the water of drainpipe equably, make last coolant-temperature gage of discharging even.

6, the utility model is by arranging a PM2.5 clarifier, the compressed air that air compressor is produced is entering before air-pressure duct transmits, it is inner that pollutant (as dust, pollen, peculiar smell, formaldehyde, bacterial virus etc.) in compressed air can be isolated in PM2.5 clarifier fully, improves the cleannes being discharged into room air.

7, in the utility model, by arranging an anion generator, make compressed air through anion generator, a large amount of electronic energies that anion generator produces are attached on the oxygen molecule in compressed air and form negative aeroion, finally be discharged into indoor, to increase the content of room air anion, be of value to the healthy of user.

8, the utility model is by arranging the 5th temperature sensor, the 6th temperature sensor and the 3rd governor motion, make the 3rd governor motion can automatically compare outside row's device for cooling with the temperature difference in compressed air air reservoir, thus adjust deflation rate in real time according to temperature difference size.When the temperature difference is large, deflation rate is high; When having a narrow range of temperature, deflation rate is low.So just can make when outside air temperature is low, be produced by compressed air generator and the compressed air rate of discharge be stored in cold-storage device also just decreases in electricity consumption ebb; When outside air temperature height, compressed air rate of discharge also just increases, and greatly reduces the unnecessary loss of compressed air with this.

Accompanying drawing explanation

Fig. 1 is structured flowchart of the present utility model.

Fig. 2 is the generalized section of drainpipe described in Fig. 1.

Fig. 3 is the cross sectional representation of drainpipe described in Fig. 1.

Detailed description of the invention

Detailed description of the invention of the present utility model is described with reference to the accompanying drawings.

With reference to Fig. 1, Fig. 2 and Fig. 3.A kind of multi-functional cooling storage air conditioning system, the row's device for cooling 4 comprising compressed air generator 1, refrigerating plant 2, cold-storage device 3 and the cold air in cold-storage device 3 is discharged.Compressed air generator 1 is communicated with cold-storage device 3 by air-pressure duct 5; Cold-storage device 3 is communicated with row's device for cooling 4; The refrigeration section 21 of refrigerating plant 2 is set in outside air-pressure duct 5, outside radiating part 22 and is arranged with the first heat reclamation device 6; The second heat reclamation device 7 is arranged with outside air-pressure duct 5 between refrigerating plant 2 and compressed air generator 1.By arranging refrigerating plant 2, first heat reclamation device 6 and the second heat reclamation device 7, the heat of the high temperature compressed air produced by compressed air generator 1 when electricity consumption ebb can be absorbed by the second heat reclamation device 7, refrigerating plant 2 successively thus form the compressed air of low temperature and enter in cold-storage device 3 to store and use in order to during peak of power consumption, and absorbed heat can also by the first heat reclamation device 6 and the second heat reclamation device 7 recycling, not only significantly enhance the effect of compressed air cooling, and greatly reduce the waste of the energy.

With reference to Fig. 1, Fig. 2 and Fig. 3.First heat reclamation device 6 offers near radiating part 22 and the side of refrigeration section 21 junction and is connected the first outside delivery port 61, offers the first water inlet 62 away from radiating part 22 and the side of refrigeration section 21 junction, the radiating part 22 of refrigerating plant 2 is equiped with the first temperature sensor 63, first delivery port 61 is equiped with the second temperature sensor and for comparing the first temperature sensor and the second temperature sensor is connected with the first temperature sensor 63, second temperature sensor signal respectively with the first governor motion 64, first governor motion 64 controlling drainage rates.In addition, first governor motion 64 comprises the first intelligent temperature comparator for comparing the first temperature sensor 63 and the second temperature sensor temperature difference and for regulating the first flow regulator of drainage rates, the first intelligent temperature comparator is connected with the first flow regulator signal.The utility model is by arranging the first temperature sensor 63, second temperature sensor and the first governor motion 64, make the first governor motion 64 automatically can compare the temperature difference of refrigerating plant radiating part 22 and the first delivery port 61, thus adjust drainage rates in real time according to temperature difference size.When the temperature difference is large, drainage rates is low; When having a narrow range of temperature, drainage rates is high.Just the coolant-temperature gage of discharging that can make like this can not be too low, and impact uses, and the coolant-temperature gage in the first heat reclamation device 6 also can not be made too high, cause energy dissipation.Simultaneously due to the effect of heat trnasfer, to be significantly higher than away from the water temperature of radiating part 22 with side, refrigeration section 21 junction near radiating part 22 and the water temperature of side, refrigeration section 21 junction, first delivery port 61 is arranged on and the coolant-temperature gage of discharging can also be made to be the highest in the first heat reclamation device 6 all the time near radiating part 22 and the side of refrigeration section 21 junction, improve the rate of recovery of heat further.

With reference to Fig. 1, Fig. 2 and Fig. 3.Second heat reclamation device 7 offers the second delivery port 71 connecting outside near the side of compressed air generator 1, the side of close refrigerating plant 2 offers the second water inlet 72; The air-pressure duct 5 being positioned at the second heat reclamation device 7 is equiped with three-temperature sensor 73; Second delivery port 71 is equiped with the 4th temperature sensor and for comparing three-temperature sensor and the 4th temperature sensor to control the second governor motion 74 of drainage rates; Second governor motion 74 is connected with three-temperature sensor 73, the 4th temperature sensor signal respectively.In addition, second governor motion 74 comprises the second intelligent temperature comparator for comparing three-temperature sensor 73 and the 4th temperature sensor temperature difference and for regulating the second flow regulator of drainage rates, the second intelligent temperature comparator is connected with the second flow regulator signal.The utility model by arranging the second heat reclamation device 7 between compressed air generator 1 and refrigerating plant 2, make compressed air before the refrigeration section 21 entering refrigerating plant 2 is freezed, first can carry out preliminary recuperation of heat by the second heat reclamation device 7, so just can reduce refrigeration section 21 for the energy consumed that freezes.And by arranging three-temperature sensor 73, the 4th temperature sensor and the second governor motion 74, second governor motion 74 can be compared automatically be positioned at the temperature difference of the second heat reclamation device 7 compressed air conduit 5 and the second delivery port 71, thus adjust drainage rates in real time according to temperature difference size.When the temperature difference is large, drainage rates is low; When having a narrow range of temperature, drainage rates is high.Just the coolant-temperature gage of discharging that can make like this can not be too low, and impact uses, and the coolant-temperature gage in the second heat reclamation device 7 also can not be made too high, cause energy dissipation.Simultaneously due to the effect of heat trnasfer, water temperature near compressed air generator 1 side will be significantly higher than the water temperature near refrigerating plant 2 side, second delivery port 71 being arranged on the coolant-temperature gage that can also make discharge near compressed air generator 1 side is the highest in the second heat reclamation device 7 all the time, improves the rate of recovery of heat further.

With reference to Fig. 1, Fig. 2 and Fig. 3.Second heat reclamation device 7 comprises water tank 75 and a draining pump 76, and water tank 75 is connected with draining pump 77 by a drainpipe 76, and drainpipe 76 is set in outside air-pressure duct; Second delivery port is opened on water tank; Second water inlet is opened on draining pump.By a drainpipe 76 sheathed outside air-pressure duct, make the water in draining pump 77 will must first through drainpipe 76 when water tank 75 is discharged, and due to water in drainpipe 76 in the unit interval by amount little, therefore can obtain the transmission of air-pressure duct 5 compressed air heat through the water of drainpipe 76 equably, make last coolant-temperature gage of discharging even.

With reference to Fig. 1, Fig. 2 and Fig. 3.Compressed air generator 1 comprises air compressor 11 and an air cleaning unit 12.Air cleaning unit 12 one end is communicated with air compressor 11, the other end is communicated with air-pressure duct 5.Air cleaning unit 12 comprises PM2.5 clarifier 121 and the anion generator 122 be communicated with this PM2.5 clarifier.By arranging a PM2.5 clarifier 121, the compressed air that air compressor 11 is produced is entering before air-pressure duct 5 transmits, it is inner that pollutant (as dust, pollen, peculiar smell, formaldehyde, bacterial virus etc.) in compressed air can be isolated in PM2.5 clarifier 121 fully, improves the cleannes being discharged into room air.By arranging an anion generator 122, make compressed air when through anion generator 122, a large amount of electronic energies that anion generator 122 produces are attached on the oxygen molecule in compressed air and form negative aeroion, finally be discharged into indoor, to increase the content of room air anion, be of value to the healthy of user.

With reference to Fig. 1, Fig. 2 and Fig. 3.Cold-storage device 3 is a compressed air air reservoir, and row's device for cooling 4 is communicated with by exhaust manifolds 8 with compressed air air reservoir.One the 5th temperature sensor 31 is equiped with outside row's device for cooling 4; One the 6th temperature sensor 32 is equiped with in compressed air air reservoir; One is equiped with for comparing the 5th temperature sensor 31 and the 6th temperature sensor 32 is connected with described 5th temperature sensor 31, the 6th temperature sensor 32 signal respectively with the 3rd governor motion the 33, three governor motion 33 controlling deflation rate in exhaust manifolds 8.In addition, 3rd governor motion 33 comprises the 3rd intelligent temperature comparator for comparing the 5th temperature sensor 31 and the 6th temperature sensor 32 temperature difference and for regulating the air damper of deflation rate, the 3rd intelligent temperature comparator is connected with air damper signal.By arranging the 5th temperature sensor 31, the 6th temperature sensor 32 and the 3rd governor motion 33, make the 3rd governor motion 33 can automatically compare outside row's device for cooling 4 with the temperature difference in compressed air air reservoir, thus adjust deflation rate in real time according to temperature difference size.When the temperature difference is large, deflation rate is high; When having a narrow range of temperature, deflation rate is low.So just can make when outside air temperature is low, be produced by compressed air generator 1 and the compressed air rate of discharge be stored in cold-storage device 3 also just decreases in electricity consumption ebb; When outside air temperature height, compressed air rate of discharge also just increases, and greatly reduces the unnecessary loss of compressed air with this.

In addition, refrigerating plant can comprise evaporimeter and the condenser be communicated with this evaporimeter that an inside is provided with cold-producing medium, and condenser is the radiating part of above-mentioned refrigerating plant, and evaporimeter is the refrigeration section of above-mentioned refrigerating plant.Compressed air is when through evaporator, heat in refrigerant suction compressed air in evaporimeter gasifies and is transferred in condenser, the cold-producing medium gasified afterwards liquefies after transferring heat to the second heat reclamation device, then is back in evaporimeter and continues to freeze to compressed air.Although the utility model can adopt this refrigeration modes, be not limited to this refrigeration modes, also can have other refrigeration modes.

With reference to Fig. 1, Fig. 2 and Fig. 3.The utility model is used when electricity consumption ebb at night, start air compressor 11 compressed air, due to can heat be produced during air compressing, therefore air compressor 11 can produce the compressed air of high temperature, high temperature compressed air, after PM2.5 clarifier 121 and anion generator 122, forms the high temperature compressed air of high-quality; One second heat reclamation device 7 is also arranged with outside air-pressure duct 4, the heat of compressed air in transmittance process on it can be delivered in the middle of the moisture in the second heat reclamation device 7 due to heat conducting effect, therefore when it is after the second heat reclamation device 7, the normal temperature compressed air of high-quality is just formed; The normal temperature compressed air of high-quality forms the compressed air of high-quality low temperature again through refrigerating plant 2, be finally stored in cold-storage device 3; The heat that refrigerating plant 2 absorbs is reclaimed by the first heat reclamation device 6 again; And the moisture after absorbing heat in the first heat reclamation device 6 and the second heat reclamation device 7 finally can be discharged into extraneous for user, as steeped hot bath etc.By day during peak of power consumption, again the compressed air in cold-storage device 3 is discharged by row's device for cooling 4, after the compressed air expansion of low temperature, temperature reduces further, therefore improve the speed that indoor environment temperature reduces, after indoor environment temperature reduces gradually, the 3rd intelligent temperature comparator in 3rd governor motion 33 senses that the temperature difference between the 5th temperature sensor 31 and the 6th temperature sensor 32 diminishes gradually, air damper just turns down deflation rate automatically, thus decreases the waste of the energy.

Above are only detailed description of the invention of the present utility model, but design concept of the present utility model is not limited thereto, all changes utilizing this design the utility model to be carried out to unsubstantiality, all should belong to the behavior of invading the utility model protection domain.

Claims (10)

1. a multi-functional cooling storage air conditioning system, it is characterized in that: comprise compressed air generator, refrigerating plant, cold-storage device and row's device for cooling that the cold air in cold-storage device is discharged, described compressed air generator is communicated with described cold-storage device by air-pressure duct, described cold-storage device is communicated with described row's device for cooling, the refrigeration section of described refrigerating plant is set in outside described air-pressure duct, the first heat reclamation device is arranged with outside radiating part, the second heat reclamation device is arranged with outside air-pressure duct between described refrigerating plant and compressed air generator.

2. a kind of multi-functional cooling storage air conditioning system as claimed in claim 1, it is characterized in that: described first heat reclamation device offers near described radiating part and the side of refrigeration section junction and is connected the first outside delivery port, side away from described radiating part and refrigeration section junction offers the first water inlet, the radiating part of described refrigerating plant is equiped with the first temperature sensor, described first delivery port is equiped with the second temperature sensor and for comparing the first temperature sensor and the second temperature sensor to control the first governor motion of drainage rates, described first governor motion respectively with described first temperature sensor, second temperature sensor signal connects.

3. a kind of multi-functional cooling storage air conditioning system as claimed in claim 2, it is characterized in that: described first governor motion comprises for the first intelligent temperature comparator of more described first temperature sensor and the second temperature sensor temperature difference and for regulating the first flow regulator of drainage rates, and described first intelligent temperature comparator is connected with described first flow regulator signal.

4. as a kind of multi-functional cooling storage air conditioning system as described in any one in claims 1 to 3, it is characterized in that: described second heat reclamation device offers near the side of described compressed air generator and connects the second outside delivery port, the second water inlet is offered near the side of described refrigerating plant, the air-pressure duct being positioned at described second heat reclamation device is equiped with three-temperature sensor, described second delivery port is equiped with the 4th temperature sensor and for comparing three-temperature sensor and the 4th temperature sensor to control the second governor motion of drainage rates, described second governor motion respectively with described three-temperature sensor, 4th temperature sensor signal connects.

5. a kind of multi-functional cooling storage air conditioning system as claimed in claim 4, it is characterized in that: described second governor motion comprises for the second intelligent temperature comparator of more described three-temperature sensor and the 4th temperature sensor temperature difference and for regulating the second flow regulator of drainage rates, and described second intelligent temperature comparator is connected with described second flow regulator signal.

6. a kind of multi-functional cooling storage air conditioning system as claimed in claim 4, it is characterized in that: described second heat reclamation device comprises a water tank and a draining pump, described water tank is connected with described draining pump by a drainpipe, described drainpipe is set in outside described air-pressure duct, described second delivery port is opened on described water tank, and described second water inlet is opened on described draining pump.

7. as a kind of multi-functional cooling storage air conditioning system as described in any one in claims 1 to 3, it is characterized in that: described compressed air generator comprises an air compressor and an air cleaning unit, described air cleaning unit one end is communicated with described air compressor, the other end is communicated with described air-pressure duct.

8. a kind of multi-functional cooling storage air conditioning system as claimed in claim 7, is characterized in that: described air cleaning unit comprises a PM2.5 clarifier and an anion generator be communicated with this PM2.5 clarifier.

9. as a kind of multi-functional cooling storage air conditioning system as described in any one in claims 1 to 3, it is characterized in that: described cold-storage device is a compressed air air reservoir, described row's device for cooling is communicated with by exhaust manifolds with described compressed air air reservoir, one the 5th temperature sensor is equiped with outside described row's device for cooling, one the 6th temperature sensor is equiped with in described compressed air air reservoir, one is equiped with for comparing the 5th temperature sensor and the 6th temperature sensor to control the 3rd governor motion of deflation rate in described exhaust manifolds, described 3rd governor motion respectively with described 5th temperature sensor, 6th temperature sensor signal connects.

10. a kind of multi-functional cooling storage air conditioning system as claimed in claim 9, it is characterized in that: described 3rd governor motion comprises for the 3rd intelligent temperature comparator of more described 5th temperature sensor and the 6th temperature sensor temperature difference and for regulating the air damper of deflation rate, and described 3rd intelligent temperature comparator is connected with described air damper signal.