CN210186795U - Shunting regeneration type zero-gas-consumption compression heat dryer - Google Patents

Abstract

The utility model discloses a zero gas consumption compression heat drying machine of reposition of redundant personnel regenerative relates to drying equipment technical field, a serial communication port, including heated gas governing valve, reposition of redundant personnel governing valve, admission valve A, admission valve B, cold blow valve A, cold blow valve B, advance cold blow valve, advance under the cooling valve, advance the heating valve, advance on the cooling valve, heating valve A, heating valve B, air outlet valve A, air outlet valve B, first absorption section of thick bamboo, second absorption section of thick bamboo, main cooler, main separator, vice separator and vice cooler. The utility model discloses be provided with heating regeneration route and cold blowing regeneration route, in heating regeneration phase and cold blowing regeneration phase, partly compressed air all can reach the air outlet pipeline through heating regeneration route or cold blowing regeneration route, and another part is then through auxiliary passage arrival air outlet pipeline, can increase compressed air's runner like this, realizes letting the purpose that complete machine loss of pressure reduces.

Description

Shunting regeneration type zero-gas-consumption compression heat dryer

Technical Field

The utility model relates to a desiccator technical field, concretely relates to zero gas consumption compression heat drying machine of reposition of redundant personnel regenerative.

Background

The application of compressed air is more and more extensive whether industrial or civil, and the compressed air purification technology is more and more advanced. Under the call of national energy conservation and environmental protection, more users tend to select energy-saving purification equipment after the comprehensive measures such as one-time investment, running cost and the like of the compressed air purification equipment are carried out. At present, although the zero-air-consumption compression heat dryer on the market is energy-saving compared with other types of suction dryers, the pressure loss of the whole machine is large due to the structure of the zero-air-consumption compression heat dryer, and the energy consumption of an air compression system is indirectly increased.

Disclosure of Invention

The utility model discloses a solve above-mentioned problem, the purpose is so realized: the shunting regeneration type zero-gas-consumption compression heat dryer is characterized by comprising a heated gas regulating valve, a shunting regulating valve, an air inlet valve A, an air inlet valve B, a cold blowing valve A, a cold blowing valve B, a cold blowing valve, a cold inlet valve lower part, a heating valve, a cooling valve upper part, a heating valve A, a heating valve B, an air outlet valve A, an air outlet valve B, a first adsorption cylinder, a second adsorption cylinder, a main cooler, a main separator, an auxiliary separator and an auxiliary cooler, wherein the heated gas regulating valve, the cold inlet valve, the heating valve B, the second adsorption cylinder, the cold blowing valve B, the cold inlet valve lower part, the auxiliary cooler, the auxiliary separator, the air inlet valve A, the first adsorption cylinder and the air outlet valve A are sequentially connected with one another through pipeline matching connectors to form a heating regeneration pipeline; the main cooler, the main separator, the cold air inlet and blowing valve, the cold air blowing valve B, the second adsorption cylinder, the heating valve B, the cold air inlet valve, the auxiliary cooler, the auxiliary separator, the air inlet valve A, the first adsorption cylinder and the air outlet valve A are sequentially connected with one another through pipeline matching connecting pieces in sequence to form a cold air blowing regeneration pipeline; the main cooler, the main separator, the flow dividing regulating valve, the air inlet valve A, the first adsorption cylinder and the air outlet valve A are sequentially connected with one another through the pipeline matching connecting pieces in sequence to form an auxiliary passage.

Preferably, the heating gas regulating valve and the flow dividing regulating valve are stepless regulating valves.

Preferably, automatic water drainers are arranged at the bottoms of the main separator and the auxiliary separator.

Preferably, the outlet valve of the heating regeneration passage is connected with an air outlet pipeline.

Preferably, the main cooler of the cold blowing regeneration passage is connected with an air inlet pipeline.

The utility model discloses following beneficial effect has:

(1) in the heating regeneration stage of the utility model, one part of compressed air reaches the air outlet through the heating regeneration passage, and the other part of compressed air reaches the air outlet through the auxiliary passage, so that the flow passage of the compressed air is increased, and the pressure loss of the whole machine is reduced;

(2) similarly, the utility model discloses in the cold blowing regeneration stage, partly compressed air reaches the air outlet through cold blowing regeneration route, and the air outlet is reachd through auxiliary passage to another part, and the compressed air runner increases, and complete machine loss of pressure reduces.

Drawings

The invention will be further explained with reference to the drawings and the specific embodiments.

Fig. 1 is a schematic connection diagram of the present invention.

Detailed Description

In order to make the technical means, creation features, achievement purposes and effects of the present invention easy to understand, the following description is combined with the detailed implementation mode to further explain the present invention.

Referring to fig. 1, the following technical solutions are adopted in the present embodiment: the shunting regeneration type zero-gas-consumption compression heat dryer is characterized by comprising a heating gas regulating valve (1), a shunting regulating valve (2), an air inlet valve A (3), an air inlet valve B (4), a cold blowing valve A (5), a cold blowing valve B (6), a cold blowing valve (7), a cooling valve inlet lower part (8), a heating valve (9), a cooling valve inlet upper part (10), a heating valve A (11), a heating valve B (12), an air outlet valve A (13), an air outlet valve B (14), a first adsorption cylinder (15), a second adsorption cylinder (16), a main cooler (17), a main separator (18), an auxiliary separator (19) and an auxiliary cooler (20), wherein the heating gas regulating valve (1), the heating valve inlet (9), the heating valve B (12), the second adsorption cylinder (16), the cold blowing valve B (6), the cooling valve inlet lower part (8), the auxiliary cooler (20), The auxiliary separator (19), the air inlet valve A (3), the first adsorption cylinder (15) and the air outlet valve A (13) are sequentially connected with one another through the pipeline matching connecting pieces in sequence to form a heating regeneration pipeline; the main cooler (17), the main separator (18), the cold-blowing valve (7), the cold-blowing valve B (6), the second adsorption cylinder (16), the heating valve B (12), the cooling-blowing valve upper part (10), the auxiliary cooler (20), the auxiliary separator (19), the air inlet valve A (3), the first adsorption cylinder (15) and the air outlet valve A (13) are sequentially connected with one another through pipeline matching connecting pieces according to the sequence to form a cold-blowing regeneration pipeline; the main cooler (17), the main separator (18), the shunt regulating valve (2), the air inlet valve A (3), the first adsorption cylinder (15) and the air outlet valve A (13) are sequentially connected with one another through pipeline matching connecting pieces to form an auxiliary passage.

The heating gas regulating valve (1) and the shunt regulating valve (2) are stepless regulating valves.

Wherein, the bottom of the main separator (18) and the auxiliary separator (19) is provided with an automatic drainer.

Wherein, an air outlet pipeline is connected to an air outlet valve A (13) of the heating regeneration passage.

Wherein, the main cooler (17) of the cold blowing regeneration passage is connected with an air inlet pipeline.

The present embodiment takes the above scheme as an example.

In the first half period, the first adsorption cylinder adsorbs the second adsorption cylinder for regeneration and is divided into two stages of heating regeneration and cold blowing regeneration.

Wherein the heating regeneration stage:

the high-temperature compressed air enters the dryer from the air inlet pipeline and then is divided into two paths, one portion of the high-temperature compressed air sequentially passes through the heating gas regulating valve, the inlet heating valve and the heating valve B and then enters the second adsorption cylinder, the high-temperature compressed air carries out heating regeneration on the adsorbent in the second adsorption cylinder, moisture is taken away by the high-temperature compressed air, then the high-temperature compressed air enters the auxiliary cooler E through the cold blow valve B and the inlet cooling valve, the compressed air is cooled and then condensed to form liquid water, the liquid water enters the auxiliary separator F, the liquid water is separated and then enters the first adsorption cylinder through the air inlet valve A, and water vapor in the compressed air is adsorbed and reaches the air outlet pipeline through the air outlet valve A. The other part of the compressed air enters the first adsorption cylinder through the shunt regulating valve and the air inlet valve A in sequence, wherein the water vapor in the compressed air is adsorbed by the adsorbent of the first adsorption cylinder, and the compressed air reaches the air outlet pipeline through the air outlet valve A.

And a cold blowing regeneration stage:

the high-temperature compressed air enters the dryer from an air inlet pipeline, the full flow passes through the main cooler C, liquid water is cooled and condensed out and then enters the main separator D, the liquid water is separated, the compressed air is divided into two paths, one portion of the liquid water enters the second adsorption cylinder through the cold blowing valve and the cold blowing valve B, the compressed air performs cold blowing regeneration on the adsorbent in the second adsorption cylinder, the heat of the adsorbent is taken away by the compressed air, the compressed air sequentially passes through the heating valve B and the cooling valve and then enters the auxiliary cooler E, the compressed air enters the first adsorption cylinder through the auxiliary separator F and the air inlet valve A after being cooled, wherein water vapor in the compressed air is adsorbed and reaches an air outlet pipeline through the air outlet valve A. And the other part of compressed air enters the first adsorption cylinder through the shunt regulating valve and the air inlet valve A, and water vapor in the compressed air is adsorbed and reaches the air outlet pipeline through the air outlet valve A.

And the principle of the second adsorption cylinder adsorbing the first adsorption cylinder for regeneration in the second half period of the work is the same as the principle.

The basic principles and the main features of the invention and the advantages of the invention have been shown and described above. It should be understood by those skilled in the art that the present invention is not limited by the foregoing embodiments, and the description of the embodiments is merely illustrative of the principles of the present invention, and that various changes and modifications may be made without departing from the spirit and scope of the present invention, and these changes and modifications are intended to fall within the scope of the present invention as claimed. The scope of the invention is defined by the appended claims and equivalents thereof.

Claims (5)

1. The shunting regeneration type zero-gas-consumption compression heat dryer is characterized by comprising a heating gas regulating valve (1), a shunting regulating valve (2), an air inlet valve A (3), an air inlet valve B (4), a cold blowing valve A (5), a cold blowing valve B (6), a cold blowing valve (7), a cooling valve inlet lower part (8), a heating valve (9), a cooling valve inlet upper part (10), a heating valve A (11), a heating valve B (12), an air outlet valve A (13), an air outlet valve B (14), a first adsorption cylinder (15), a second adsorption cylinder (16), a main cooler (17), a main separator (18), an auxiliary separator (19) and an auxiliary cooler (20), wherein the heating gas regulating valve (1), the heating valve inlet (9), the heating valve B (12), the second adsorption cylinder (16), the cold blowing valve B (6), the cooling valve inlet lower part (8), the auxiliary cooler (20), The auxiliary separator (19), the air inlet valve A (3), the first adsorption cylinder (15) and the air outlet valve A (13) are sequentially connected with one another through the pipeline matching connecting pieces in sequence to form a heating regeneration pipeline; the main cooler (17), the main separator (18), the cold-blowing valve (7), the cold-blowing valve B (6), the second adsorption cylinder (16), the heating valve B (12), the cooling-blowing valve upper part (10), the auxiliary cooler (20), the auxiliary separator (19), the air inlet valve A (3), the first adsorption cylinder (15) and the air outlet valve A (13) are sequentially connected with one another through pipeline matching connecting pieces according to the sequence to form a cold-blowing regeneration pipeline; the main cooler (17), the main separator (18), the shunt regulating valve (2), the air inlet valve A (3), the first adsorption cylinder (15) and the air outlet valve A (13) are sequentially connected with one another through pipeline matching connecting pieces to form an auxiliary passage.

2. The split regenerative zero gas consumption compression heat dryer according to claim 1, wherein the heating gas regulating valve (1) and the split regulating valve (2) are stepless regulating valves.

3. A split-flow regenerative zero-gas-consumption compression heat dryer according to claim 1, characterized in that automatic water drains are provided at the bottom of the primary separator (18) and the secondary separator (19).

4. The split-flow regenerative zero-gas-consumption compression heat dryer of claim 1, wherein the outlet valve a (13) of the heating regeneration path is connected with an air outlet pipeline.

5. A split-flow regenerative zero-gas-consumption compression heat dryer according to claim 1, characterized in that the main cooler (17) of the cold-blown regeneration path is connected with an air inlet line.

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