CN218011948U - High-efficiency energy-saving dryer - Google Patents

Abstract

The utility model relates to an energy-efficient desiccator relates to compressed air drying technical field, and it includes a set of frame, all set up the adsorption tower in the frame, set up the adsorbent in the adsorption tower, the adsorption tower bottom sets up the admission line, the adsorption tower top sets up the pipeline of giving vent to anger, set up regeneration pipeline and exhaust duct on the adsorption tower lateral wall, all set up the groove of sliding on the frame opposite face, the inslot cunning that slides sets up the sliding block, sliding block and adsorption tower fixed connection, the groove of sliding is close to frame bottom one and serves fixed pressure sensor that sets up, the inslot that slides sets up supporting component, supporting component is used for supporting the sliding block. The gas consumption of the equipment is reduced, and the energy loss is reduced.

Description

High-efficiency energy-saving dryer

Technical Field

The utility model belongs to the technical field of the compressed air drying technique and specifically relates to an energy-efficient type desiccator is related to.

Background

Common compressed air dryers are classified into a freezing type compressed air dryer and an adsorption type compressed air dryer. The refrigeration type compressed air dryer can further separate out moisture in the air to obtain drier air by reducing the air temperature. The adsorption type compressed air dryer enables air to pass through the adsorbent through the principle of pressure swing adsorption, and then moisture is adsorbed by the adsorbent to obtain dry air.

Current adsorption dryer, it includes the chassis, and fixed a set of adsorption tower that sets up on the chassis sets up the adsorbent layer in the adsorption tower, and the common intercommunication in adsorption tower bottom sets up the admission line, sets up air inlet on the admission line, and the common intercommunication in adsorption tower top sets up the pipeline of giving vent to anger, sets up the air outlet on the pipeline of giving vent to anger. Air to be dried enters the air inlet pipeline from the air inlet and then enters one of the adsorption towers from the air inlet pipeline to be adsorbed by the adsorbent layer, so that dry regenerated gas is obtained. When the adsorbent layer in the adsorption tower is saturated, a part of the regenerated gas is decompressed and expanded to atmospheric pressure and introduced into the adsorption tower, so that the regenerated gas adsorbs the moisture in the adsorbent layer, and the effects of cyclic regeneration and continuous air drying of the two adsorption towers are realized.

In the adsorption dryer use, can set up the switching time usually, as long as the time arrives just to switch the adsorption tower and let in quantitative air and dry, nevertheless because the air humidity of different environment different times is different, and then there is the adsorbent layer not to use complete condition, and then it is extravagant to have some air in the air admission adsorption tower after the drying.

SUMMERY OF THE UTILITY MODEL

In order to reduce the gas consumption of equipment and reduce the loss of energy, the application provides a high-efficiency energy-saving dryer.

The application provides a high-efficient energy-saving desiccator adopts following technical scheme:

the utility model provides an energy-efficient desiccator, includes a set of frame, all set up the adsorption tower in the frame, set up the adsorbent in the adsorption tower, the adsorption tower bottom sets up the admission line, the adsorption tower top sets up the pipeline of giving vent to anger, set up regeneration pipeline and exhaust duct on the adsorption tower lateral wall, all set up the groove of sliding on the frame opposite face, the inslot that slides sets up the sliding block, sliding block and adsorption tower fixed connection, the groove of sliding is close to frame bottom one and serves fixedly and set up pressure sensor, set up the supporting component in the groove of sliding, the supporting component is used for supporting the sliding block.

By adopting the technical scheme, the air to be dried is introduced into one of the adsorption towers through the air inlet pipeline, the adsorbent in the adsorption tower adsorbs the water vapor in the air, the air is dried to form the regenerated gas, the formed regenerated gas is output from the air outlet pipeline, the water vapor is gradually absorbed by the adsorbent in the adsorption tower, the weight of the adsorption tower is increased, the supporting component is further compressed, the adsorption tower drives the sliding block to move downwards, after the adsorbent in the adsorption tower is saturated, the adsorption tower moves downwards to drive the sliding block to slide to be in contact with the pressure sensor, after the pressure sensor receives a pressure signal, the air to be dried is introduced into the other adsorption tower to be dried, the regenerated gas is introduced into the adsorption tower through the regeneration pipeline, the regenerated gas in the adsorbent is adsorbed by the regenerated gas and is discharged through the discharge pipeline, the condition that the adsorbent is not saturated is further reduced, the gas consumption of equipment is reduced, and the loss of energy is reduced.

Preferably, the supporting assembly comprises a plurality of supporting springs, a plurality of supporting grooves are formed in one end, close to the bottom of the rack, of the sliding groove, one ends of the supporting springs are fixedly connected with the bottom of the sliding block, and the other ends of the supporting springs are fixedly connected with the bottom wall of the supporting groove.

Through adopting above-mentioned technical scheme, when the adsorbent in the adsorption tower is in unsaturated state, supporting spring supports the sliding block, make the sliding block bottom not contact with pressure sensor, and then treat that dry gas continues to let in this adsorption tower, when the adsorbent in the adsorption tower is in saturated state, the adsorption tower weight increases, and then the sliding block receives decurrent effort increase, and then the sliding block makes supporting spring compress to in supporting the groove, the sliding block diapire contacts with pressure sensor, and then reduce the adsorbent and do not use the condition of saturation, reduce the gas consumption volume of equipment, the loss of the energy is reduced.

Preferably, the supporting assembly further comprises a plurality of guide rods, the supporting springs are sleeved on the guide rods, one ends of the guide rods are fixedly connected with the inner wall of the sliding groove close to the top of the rack, and the other ends of the guide rods penetrate through the sliding block and are fixedly connected with the bottom wall of the supporting groove.

Through adopting above-mentioned technical scheme, when the sliding block moved down compression supporting spring, the sliding block set up the direction along the guide bar and slides, and supporting spring sets up the direction compression along the guide bar, and then reduces the condition that the sliding block dropped the sliding groove, reduces the condition of buckling among the supporting spring compression process, and then reduces the sliding block and touches the condition that leads to the adsorbent not to be saturated with pressure sensor mistake, reduces the gas consumption volume of equipment, reduces the loss of the energy.

Preferably, an air inlet box is fixedly arranged between the racks, one end of the air inlet pipeline is communicated with the bottom of the adsorption tower, the other end of the air inlet pipeline is communicated with the air inlet box, and the air inlet pipeline is provided with an air inlet electromagnetic valve.

Through adopting above-mentioned technical scheme, open one of them air inlet solenoid valve, make the incasement of admitting air treat dry gas and get into the adsorption tower by the admission line and carry out the drying, when the absorption in this adsorption tower is saturated, the air inlet solenoid valve of being connected with this adsorption tower closes, another air inlet solenoid valve opens, and then treat dry gas and get into another adsorption tower and carry out the drying, let in regeneration gas in this adsorption tower and carry out regeneration treatment, when the absorption in another adsorption tower is saturated, the air inlet solenoid valve on another adsorption tower closes, the air inlet solenoid valve on this adsorption tower opens, and then realize the switching between the adsorption tower, make the adsorbent in the adsorption tower use the saturation, reduce the gas consumption volume.

Preferably, a group of air inlet holes are formed in the top of the air inlet box, one end, far away from the adsorption tower, of one air inlet pipeline is inserted into one air inlet hole, one end, far away from the adsorption tower, of the other air inlet pipeline is inserted into the other air inlet hole, a first sealing ring piece is sleeved on the air inlet pipeline, and the first sealing ring piece is fixedly connected with the inner wall of the air inlet box.

Through adopting above-mentioned technical scheme, when the adsorption tower reciprocated, the adsorption tower drove the admission line and reciprocated, and then the admission line slides from top to bottom and makes sealing ring piece take place elastic deformation in going into the gas vent, and sealing ring piece one reduces the condition of going into gas tank internal gas loss.

Preferably, a regeneration gas box is fixedly arranged between the racks, one end of the gas outlet pipeline is communicated with the top of the adsorption tower, the other end of the gas outlet pipeline is communicated with the regeneration gas box, and a gas outlet electromagnetic valve is arranged on the gas outlet pipeline.

Through adopting above-mentioned technical scheme, when one of them adsorption tower carries out the drying to gas, the solenoid valve of giving vent to anger of this adsorption tower is opened, makes the interior regeneration gas of this adsorption tower get into the regeneration gas case by the pipeline of giving vent to anger, and the solenoid valve of giving vent to anger of another adsorption tower is closed, reduces the condition that the regeneration gas excessively flowed into in another adsorption tower, reduces the waste of regeneration gas.

Preferably, the bottom of the regeneration gas tank is provided with a group of gas outlet holes, one end of one gas outlet pipeline, which is far away from the adsorption tower, is inserted into one gas outlet hole, the other end of the other gas outlet pipeline, which is far away from the adsorption tower, is inserted into the other gas outlet hole, the gas outlet pipeline is sleeved with a second sealing ring sheet, and the second sealing ring sheet is fixedly connected with the inner wall of the regeneration gas tank.

Through adopting above-mentioned technical scheme, when the adsorption tower reciprocated, the adsorption tower drove the pipeline of giving vent to anger and reciprocates, and then the pipeline of giving vent to anger slides from top to bottom in gas outlet department and makes two sealing ring piece take place elastic deformation, and two sealing ring piece reduce the condition that regeneration gas runs off in the regeneration gas case, reduce the waste of regeneration gas.

Preferably, the bottom of the regeneration gas tank is communicated with a group of first connecting pipes, the first connecting pipes are slidably arranged in the second connecting pipes, one ends, far away from the first connecting pipes, of the second connecting pipes are communicated with one regeneration pipeline, the other ends, far away from the first connecting pipes, of the second connecting pipes are communicated with the other regeneration pipeline, regeneration electromagnetic valves are arranged on the regeneration pipelines, and exhaust electromagnetic valves are arranged on the exhaust pipelines.

Through adopting above-mentioned technical scheme, when the adsorption tower reciprocated, the adsorption tower drove regeneration pipeline and exhaust duct reciprocated, regeneration pipeline slides in connecting pipe one and connecting pipe two respectively, when the adsorption tower carries out the drying to gas, close regeneration solenoid valve and exhaust solenoid valve, and then gas is dried in the adsorption tower, when the adsorption tower regenerates, open regeneration solenoid valve and exhaust solenoid valve, and then the regeneration gas reduces the water in the adsorbent by regeneration box entering adsorption tower in, and discharge outside the adsorption tower through exhaust duct, reduce the condition in the too much inflow adsorption tower of regeneration gas, reduce the waste of regeneration gas.

In summary, the present application includes at least one of the following beneficial technical effects:

1. by arranging the frame, the adsorption tower, the adsorbent, the air inlet pipeline, the air outlet pipeline, the exhaust pipeline, the regeneration pipeline, the sliding groove, the sliding block, the pressure sensor and the supporting component, the condition that the adsorbent is not used and saturated is reduced, the air consumption of equipment is reduced, and the energy loss is reduced;

2. by arranging the supporting springs and the supporting grooves, the gas consumption of the equipment is reduced, and the energy loss is reduced;

3. through setting up the guide bar, reduce the slider and touch the condition that leads to the adsorbent not to saturate with pressure sensor mistake, reduce the gas consumption volume of equipment.

Drawings

Fig. 1 is a schematic structural diagram of an energy-efficient dryer in an embodiment of the present application.

Fig. 2 is a sectional view showing a connection relationship between a support assembly and a frame according to an embodiment of the present application.

Fig. 3 is a sectional view of an energy efficient dryer according to an embodiment of the present application.

Description of reference numerals: 1. a frame; 11. a gas inlet box; 111. air inlet holes; 12. a regeneration gas tank; 121. an air outlet; 2. an adsorption tower; 21. an adsorbent; 3. an air intake duct; 31. an air inlet solenoid valve; 32. a first sealing ring sheet; 4. an air outlet pipe; 41. an air outlet electromagnetic valve; 42. a second sealing ring sheet; 5. a regeneration pipeline; 51. a regenerative solenoid valve; 52. a first connecting pipe; 53. a second connecting pipe; 6. an exhaust duct; 61. an exhaust solenoid valve; 7. a sliding groove; 71. a sliding block; 8. a support assembly; 81. a support spring; 811. a support groove; 82. a guide bar; 9. a pressure sensor.

Detailed Description

The present application is described in further detail below with reference to figures 1-3.

The embodiment of the application discloses energy-efficient type desiccator. Referring to fig. 1 and 2, the device comprises a set of machine frame 1, and sliding grooves 7 are symmetrically formed in the opposite surfaces of the machine frame 1 along the height direction of the machine frame 1. The sliding block 71 is arranged in the sliding groove 7 in a sliding mode, and the outer wall of the sliding block 71 is attached to the inner wall of the sliding groove 7. The sliding block 71 supports and installs the adsorption tower 2, and the outer wall of the adsorption tower 2 is welded with the sliding block 71. The adsorbent 21 is filled in the adsorption tower 2, and the adsorbent 21 is made of an activated alumina material. 2 bottom installation admission line 3 of adsorption tower, the last installation of admission line 3 intake solenoid valve 31, 3 one end of admission line and 2 intercommunications of adsorption tower, the 3 other ends of admission line with treat that dry air source communicates each other. The top of the adsorption tower 2 is provided with an air outlet pipeline 4, the air outlet pipeline 4 is provided with an air outlet electromagnetic valve 41, one end of the air outlet pipeline 4 is communicated with the top of the adsorption tower 2, and the other end of the air outlet pipeline 4 is communicated with a regenerated gas source. A regeneration pipeline 5 and an exhaust pipeline 6 are installed on the side wall of the adsorption tower 2, the regeneration pipeline 5 is located above the exhaust pipeline 6, a regeneration electromagnetic valve 51 is installed on the regeneration pipeline 5, and an exhaust electromagnetic valve 61 is installed on the exhaust pipeline 6. And a pressure sensor 9 is arranged at one end of the sliding chute 7 close to the bottom of the frame 1, and the pressure sensor 9 is used for detecting the pressure of the sliding block 71. A supporting component 8 is arranged in the sliding groove 7, and the supporting component 8 is used for supporting the sliding block 71. When one of the adsorption towers 2 adsorbs gas moisture, the air inlet electromagnetic valve 31 and the air outlet electromagnetic valve 41 on the adsorption tower 2 open the regeneration electromagnetic valve 51 and the air outlet electromagnetic valve 61 to be closed, air to be dried is introduced into the adsorption tower 2 through the air inlet pipeline 3, the adsorbent 21 in the adsorption tower 2 adsorbs the moisture in the air, the air is dried to form regeneration gas, and the formed regeneration gas is output from the air outlet pipeline 4. The adsorbent 21 in the adsorption tower 2 absorbs steam gradually, and then makes the increase of weight of adsorption tower 2, and the increase of weight of adsorption tower 2 and then compression supporting component 8 make the adsorption tower 2 drive sliding block 71 move down. When the adsorbent 21 in the adsorption tower 2 is saturated, the adsorption tower 2 moves downward to drive the sliding block 71 to slide to contact with the pressure sensor 9. Further, the pressure sensor 9 receives the pressure signal, the air inlet solenoid valve 31 and the air outlet solenoid valve 41 on this adsorption tower 2 are closed and the regeneration solenoid valve 51 and the air outlet solenoid valve 61 are opened, and the air inlet solenoid valve 31 and the air outlet solenoid valve 41 on the other adsorption tower 2 are opened and the regeneration solenoid valve 51 and the air outlet solenoid valve 61 are closed. And introducing the air to be dried into the other adsorption tower 2 for drying, introducing regenerated gas into the adsorption tower 2 through a regeneration pipeline 5, adsorbing the water vapor in the adsorbent 21 by the regenerated gas, and discharging the water vapor through a discharge pipeline. Further, the situation that the adsorbent 21 is not saturated is reduced, the gas consumption of equipment is reduced, and the energy loss is reduced.

In order to support the sliding block 71 and make the sliding block 71 bring the adsorption tower 2 back to the original position, referring to fig. 1 and 2, the support assembly 8 includes a plurality of support springs 81 and a plurality of guide rods 82. One end of the sliding groove 7 close to the bottom of the frame 1 is provided with a plurality of supporting grooves 811 along the height direction of the frame 1, and the guide rod 82 is arranged in the supporting grooves 811 along the height direction of the frame 1. One end of the guide rod 82 is welded with the bottom wall of the support groove 811, and the other end of the guide rod 82 penetrates through the sliding block 71 and is welded with the inner wall of the sliding groove 7 close to the top of the rack 1. The supporting spring 81 is sleeved on the guide rod 82, one end of the supporting spring 81 is welded with the bottom of the sliding block 71, and the other end of the supporting spring 81 is welded with the bottom wall of the supporting groove 811. When the sliding block 71 moves downwards to compress the supporting spring 81, the sliding block 71 slides along the arrangement direction of the guide rod 82, the supporting spring 81 is compressed along the arrangement direction of the guide rod 82, the situations that the sliding block 71 falls off the sliding groove 7 and the supporting spring 81 is bent are further reduced, and the situation that the adsorbent 21 is not saturated due to mistaken touch of the sliding block 71 and the pressure sensor 9 is reduced. When the adsorbent 21 in the adsorption tower 2 is in an unsaturated state, the support spring 81 supports the sliding block 71, so that the bottom of the sliding block 71 is not in contact with the pressure sensor 9, and the gas to be dried is continuously introduced into the adsorption tower 2. When the adsorbent 21 in the adsorption tower 2 is in a saturated state, the weight of the adsorption tower 2 is increased, further, the downward acting force of the sliding block 71 is increased, so that the supporting spring 81 is compressed into the supporting groove 811, the bottom wall of the sliding block 71 is contacted with the pressure sensor 9, the gas consumption of the equipment is reduced, and the energy loss is reduced.

In order to saturate the adsorbent 21 in the adsorption tower 2, referring to fig. 2 and 3, the gas inlet box 11 is installed on the frame 1, the bottom of the gas inlet box 11 is welded to the frame 1, the gas inlet box 11 is located below the adsorption tower 2, and the gas to be dried is stored in the gas inlet box 11. The top of the air inlet box 11 is provided with a group of air inlet holes 111, wherein one end of one air inlet pipeline 3 far away from the adsorption tower 2 is inserted into one air inlet hole 111, and one end of the other air inlet pipeline 3 far away from the adsorption tower 2 is inserted into the other air inlet hole 111. The first sealing ring piece 32 is installed on the air inlet pipeline 3, and the first sealing ring piece 32 is fixedly connected with the inner wall of the air inlet box 11. When the adsorption tower 2 moves up and down, the adsorption tower 2 drives the air inlet pipeline 3 to move up and down, and then the air inlet pipeline 3 slides up and down at the air inlet hole 111 and makes the first sealing ring piece 32 elastically deform, and the first sealing ring piece 32 reduces the gas loss in the air inlet box 11. And opening one of the air inlet electromagnetic valves 31 to enable the gas to be dried in the air inlet box 11 to enter the adsorption tower 2 from the air inlet pipeline 3 for drying. When the adsorption in the adsorption tower 2 is saturated, the air inlet electromagnetic valve 31 connected with the adsorption tower 2 is closed, the other air inlet electromagnetic valve 31 is opened, and then the dry gas enters the other adsorption tower 2 for drying, and the regeneration gas is introduced into the adsorption tower 2 for regeneration treatment. When the adsorption in the other adsorption tower 2 is saturated, the air inlet electromagnetic valve 31 on the other adsorption tower 2 is closed, and the air inlet electromagnetic valve 31 on the adsorption tower 2 is opened, so that the switching between the adsorption towers 2 is realized, the adsorbent 21 in the adsorption tower 2 is saturated, and the gas consumption is reduced.

In order to reduce the waste of the regeneration gas, referring to fig. 2 and 3, a regeneration gas box 12 is installed on the top of the frame 1, the bottom wall of the regeneration gas box 12 is welded with the top wall of the frame 1, and the regeneration gas box 12 is positioned above the adsorption tower 2. A group of air outlet holes 121 are formed in the bottom of the regeneration air box 12, one end of one air outlet pipeline 4, which is far away from the adsorption tower 2, is inserted into one air outlet hole 121, and one end of the other air outlet pipeline 4, which is far away from the adsorption tower 2, is inserted into the other air outlet hole 121. The second sealing ring plate 42 is sleeved on the gas outlet pipeline 4, and the second sealing ring plate 42 is fixedly connected with the inner wall of the regeneration gas tank 12. The second seal ring 42 reduces the loss of regeneration gas from the regeneration gas tank 12. When the adsorption tower 2 dries the gas, the gas outlet electromagnetic valve 41 of the adsorption tower 2 is opened, so that the regenerated gas in the adsorption tower 2 enters the regenerated gas box 12 through the gas outlet pipeline 4, and the gas outlet electromagnetic valve 41 of the other adsorption tower 2 is closed, thereby reducing the situation that the regenerated gas excessively flows into the other adsorption tower 2 and reducing the waste of the regenerated gas.

Referring to fig. 2 and 3, a first connecting pipe 52 is disposed at the bottom of the regeneration gas tank 12, a second connecting pipe 53 is slidably disposed in the first connecting pipe 52, an inner wall of the first connecting pipe 52 is attached to an outer wall of the second connecting pipe 53, one end of the second connecting pipe 53 away from the first connecting pipe 52 is communicated with one of the regeneration pipes 5, and one end of the second connecting pipe 53 away from the first connecting pipe 52 is communicated with the other regeneration pipe 5. When adsorption tower 2 reciprocates, adsorption tower 2 drives regeneration pipeline 5 and exhaust duct 6 and reciprocates, and regeneration pipeline 5 slides in connecting pipe one 52 and connecting pipe two 53 respectively, when adsorption tower 2 carries out the drying to gas, closes regeneration solenoid valve 51 and exhaust solenoid valve 61, and then gas carries out the drying in adsorption tower 2. When the adsorption tower 2 is regenerated, the regeneration electromagnetic valve 51 and the exhaust electromagnetic valve 61 are opened, and the regeneration gas enters the adsorption tower 2 from the regeneration box to reduce the moisture in the adsorbent 21, and is discharged out of the adsorption tower 2 through the exhaust pipeline 6. The situation that the regeneration gas excessively flows into the adsorption tower 2 is reduced, and the waste of the regeneration gas is reduced.

The implementation principle of the high-efficiency energy-saving dryer in the embodiment of the application is as follows: when one of the adsorption towers 2 adsorbs gas moisture, the air inlet electromagnetic valve 31 and the air outlet electromagnetic valve 41 on the adsorption tower 2 open the regeneration electromagnetic valve 51 and the air outlet electromagnetic valve 61 to be closed, air to be dried is introduced into the adsorption tower 2 through the air inlet pipeline 3, the adsorbent 21 in the adsorption tower 2 adsorbs the moisture in the air, the air is dried to form regeneration gas, and the formed regeneration gas is output from the air outlet pipeline 4. When the adsorbent 21 in the adsorption tower 2 is in an unsaturated state, the support spring 81 supports the sliding block 71, so that the bottom of the sliding block 71 is not in contact with the pressure sensor 9, and the gas to be dried is continuously introduced into the adsorption tower 2. When the adsorbent 21 in the adsorption tower 2 is saturated, the weight of the adsorption tower 2 increases, and the downward force applied to the slide block 71 increases to compress the support spring 81 into the support groove 811, so that the bottom wall of the slide block 71 contacts the pressure sensor 9. Further, the pressure sensor 9 receives a pressure signal, the inlet solenoid valve 31 and the outlet solenoid valve 41 of the adsorption tower 2 are closed and the regeneration solenoid valve 51 and the exhaust solenoid valve 61 are opened, and the inlet solenoid valve 31 and the outlet solenoid valve 41 of the other adsorption tower 2 are opened and the regeneration solenoid valve 51 and the exhaust solenoid valve 61 are closed. A part of the regeneration gas is introduced into this adsorption tower 2 through the regeneration duct 5 to reduce the moisture in the adsorbent 21, and the air to be dried is introduced into the other adsorption tower 2 to be dried. Further, the situation that the adsorbent 21 is not saturated is reduced, the gas consumption of equipment is reduced, and the energy loss is reduced.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. The utility model provides an energy-efficient type desiccator, includes a set of frame (1), all set up adsorption tower (2) in frame (1), set up adsorbent (21) in adsorption tower (2), adsorption tower (2) bottom sets up admission line (3), adsorption tower (2) top sets up pipeline (4) of giving vent to anger, set up regeneration duct (5) and exhaust duct (6), its characterized in that on adsorption tower (2) lateral wall: all set up groove (7) that slides on frame (1) the opposite face, the inslot that slides (7) is interior to slide and sets up sliding block (71), sliding block (71) and adsorption tower (2) fixed connection, sliding block (7) are close to frame (1) bottom one and serve fixed pressure sensor (9) that set up, set up supporting component (8) in groove (7) slides, supporting component (8) are used for supporting sliding block (71).

2. An energy efficient dryer as claimed in claim 1, wherein: the supporting component (8) comprises a plurality of supporting springs (81), one end, close to the bottom of the rack (1), of the sliding groove (7) is provided with a plurality of supporting grooves (811), one end of each supporting spring (81) is fixedly connected with the bottom of the sliding block (71), and the other end of each supporting spring (81) is fixedly connected with the bottom wall of each supporting groove (811).

3. An energy-efficient dryer according to claim 2, wherein: the supporting component (8) further comprises a plurality of guide rods (82), the supporting spring (81) is sleeved on the guide rods (82), one end of each guide rod (82) is close to the inner wall fixed connection of the top of the rack (1) with the sliding groove (7), and the other end of each guide rod (82) penetrates through the sliding block (71) and the bottom wall fixed connection of the supporting groove (811).

4. An energy-efficient dryer according to claim 2, wherein: the fixed gas tank (11) of putting into of establishing on frame (1), admission line (3) one end and adsorption tower (2) bottom communicate with each other, admission line (3) the other end and the intercommunication of income gas tank (11) each other, set up air inlet solenoid valve (31) on admission line (3).

5. An energy-efficient dryer according to claim 4, wherein: the top of the air inlet box (11) is provided with a group of air inlet holes (111), one end, far away from the adsorption tower (2), of one air inlet pipeline (3) is inserted into one air inlet hole (111), the other end, far away from the adsorption tower (2), of the other air inlet pipeline (3) is inserted into the other air inlet hole (111), the air inlet pipeline (3) is sleeved with a first sealing ring piece (32), and the first sealing ring piece (32) is fixedly connected with the inner wall of the air inlet box (11).

6. An energy efficient dryer as claimed in claim 2, wherein: the machine is characterized in that a regeneration gas box (12) is fixedly arranged on the rack (1), one end of the gas outlet pipeline (4) is communicated with the top of the adsorption tower (2), the other end of the gas outlet pipeline (4) is communicated with the regeneration gas box (12), and a gas outlet electromagnetic valve (41) is arranged on the gas outlet pipeline (4).

7. An energy efficient dryer as claimed in claim 6, wherein: a group of air outlet holes (121) are formed in the bottom of the regeneration air box (12), one end, far away from the adsorption tower (2), of one air outlet pipeline (4) is inserted into one air outlet hole (121), the other end, far away from the adsorption tower (2), of the other air outlet pipeline (4) is inserted into the other air outlet hole (121), a second sealing ring piece (42) is sleeved on the air outlet pipeline (4), and the second sealing ring piece (42) is fixedly connected with the inner wall of the regeneration air box (12).

8. An energy efficient dryer as claimed in claim 6, wherein: the regeneration gas tank (12) bottom intercommunication sets up a set of connecting pipe one (52), connecting pipe two (53) are set up in the sliding movement in connecting pipe one (52), one of them connecting pipe two (53) are kept away from connecting pipe one (52) one end and are communicate with one of them regeneration pipeline (5) each other, another connecting pipe two (53) are kept away from connecting pipe one (52) one end and communicate with another regeneration pipeline (5) each other, set up regeneration solenoid valve (51) on regeneration pipeline (5), set up exhaust solenoid valve (61) on exhaust duct (6).

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