CN210663819U

CN210663819U - Energy-saving dehumidification drying system

Info

Publication number: CN210663819U
Application number: CN201822054409.8U
Authority: CN
Inventors: 王雪彪
Original assignee: Dongguan Gainwal Plastic Machiney Co ltd
Current assignee: Dongguan Gainwal Plastic Machiney Co ltd
Priority date: 2018-12-08
Filing date: 2018-12-08
Publication date: 2020-06-02
Anticipated expiration: 2028-12-08

Abstract

The utility model relates to the technical field of feed conveying, in particular to an energy-saving dehumidifying and drying system, which comprises a drying unit, a first material conveying blast pipe, a second material conveying blast pipe and a dehumidifier arranged on the right side of the drying unit, wherein the dehumidifier comprises a catcher, a drying machine, a honeycomb runner, a drying treatment system and a regeneration system; the top end of each drier in the drier set is provided with a catcher for materials to enter. The bottom end opening of the catcher is connected with the top end opening of the drying machine, the top end of each drying machine in the drying machine set is provided with a first air conveying port and a second air conveying port, the first air conveying port is connected with a first material conveying air supply pipe, and the second air conveying port is connected with a second material conveying air supply pipe; first defeated material blast pipe and second defeated material blast pipe are connected through the left side opening of drying process system with the honeycomb runner, and rotary dehumidifier's right side opening is connected with regeneration system, the utility model has the advantages of energy-conservation, improvement work efficiency.

Description

Energy-saving dehumidification drying system

Technical Field

The utility model relates to a technical field is carried to the feed, concretely relates to energy-conserving dehumidification drying system.

Background

In the existing dehumidification drying system, in the process of conveying raw materials into an injection molding machine after dehumidification and drying, generally, one dehumidifier needs to be connected with more than two drying units in series, when the number of the drying units is large, the dehumidification control system has a complex structure, the air quantity of the dehumidification control system can not be well controlled, and the effect after dehumidification and drying can not be accurately controlled, so that energy waste is caused.

Therefore, it is necessary to provide a technical means to solve the above-mentioned drawbacks.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome prior art's defect, provide energy-conserving dehumidification drying system to there is energy-conserving dehumidification drying system can not control dehumidification control system's the amount of wind betterly among the solution prior art, and accurate control can not be accomplished to the effect after the dehumidification drying, leads to the extravagant problem of the energy.

The utility model discloses a realize like this, energy-conserving dehumidification drying system, including drying unit, first defeated blast pipe, second defeated blast pipe and set up the dehumidifier on the right side of drying unit, its characterized in that, the dehumidifier includes trap, desiccator, honeycomb runner, drying process system and regeneration system; wherein the content of the first and second substances,

the top end of each drier in the drier set is provided with a catcher for materials to enter.

The bottom end opening of the catcher is connected with the top end opening of the drying machine, the top end of each drying machine in the drying machine set is provided with a first air conveying port and a second air conveying port, the first air conveying ports are connected with a first conveying air supply pipe through a pipeline A, and the second air conveying ports are connected with a second conveying air supply pipe through a pipeline B;

the first material conveying air supply pipe and the second material conveying air supply pipe are connected with the left opening of the honeycomb rotating wheel through the drying treatment system, and the right opening of the rotating wheel dehumidifier is connected with the regeneration system.

Preferably, the first material conveying air supply pipe and the second material conveying air supply pipe are respectively provided with a plurality of air intercepting valves, and the air intercepting valves are arranged on the pipeline A and the pipeline B.

Preferably, the drying treatment system comprises a hopper fan, a drying filter, a cooler, a heater and a Roots variable frequency fan; the top end opening of the drying filter is connected with the first material conveying air supply through a vertical upward pipeline, the right side opening of the drying filter is connected with the top end right side opening of the cooler, the top end left side opening of the cooler is connected with the Roots variable frequency fan, and the Roots variable frequency fan penetrates through the honeycomb rotating wheel through a section of rightward pipeline C to extend to the right side of the hopper fan and is connected with the hopper fan; the hopper fan is connected with the bottom opening of the heater; a pipeline D is branched from a connecting pipeline between the drying filter and the cooler, and the pipeline D is arranged on the honeycomb rotating wheel in a penetrating way and connected to a pipeline between the Roots variable frequency fan and the heater; the top opening of the heater is connected with one end of the second material conveying air supply pipe; the second material conveying air supply pipe is connected with a second air transmission port of the dryer and is provided with an exhaust opening penetrating into the dryer and facing the bottom end of the dryer.

Preferably, the exhaust opening is in an inverted triangle shape.

Preferably, the regeneration system comprises a regeneration drying filter, a regeneration roots variable frequency fan and a regeneration heater, a pipeline E connected with an opening at the top end of the regeneration heater is arranged on the honeycomb rotating wheel, an opening at the bottom end of the regeneration heater is connected with the regeneration roots variable frequency fan, and the regeneration roots variable frequency fan is connected with the regeneration drying filter rightwards.

Preferably, the cell wheel comprises sector a, sector B and sector C; pipeline C wears to locate sector A in the honeycomb runner, pipeline D wears to locate sector B in the honeycomb runner, pipeline E wears to locate sector C in the honeycomb runner.

The utility model discloses an energy-conserving dehumidification drying system's technological effect does:

1. this application simple structure, optimization system structure utilize roots's frequency conversion fan control dehumidification drying system's amount of wind, when using many desiccators, can better control dehumidification drying system's the amount of wind, play energy-conserving effect.

2. Set up regeneration system, heat inspiratory air and get into the honeycomb runner again, break away from adsorbed moisture in the honeycomb runner and discharged by the fan to make the honeycomb runner resume the moisture absorption function and accomplish regeneration process, the honeycomb runner can uninterrupted duty, guarantee work efficiency.

Drawings

FIG. 1: the embodiment of the utility model provides an energy-conserving dehumidification drying system's overall structure schematic diagram is related.

FIG. 2: the embodiment of the utility model provides a dehumidifier's overall structure schematic diagram is related.

Detailed Description

In order to make the objects, technical solutions and advantages of the present invention more clearly understood, the present invention is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

It will be understood that when an element is referred to as being "secured to" or "disposed on" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected to" another element, it can be directly connected to the other element or intervening elements may also be present. When an element is referred to as being "fixedly attached" to another element, it can be fixedly attached by welding, bolting, gluing, or the like.

Please refer to fig. 1, which is an embodiment of the present invention, and the energy-saving dehumidifying and drying system in this embodiment is used for dehumidifying and drying materials in the feeding system, the energy-saving dehumidifying and drying system in this embodiment includes a drying unit 10, a first material conveying blast pipe 40, a second material conveying blast pipe 30, and a dehumidifier 20 disposed on the right side of the drying unit 10, and each component of the energy-saving dehumidifying and drying system is further described as follows:

the top end of each dryer in the dryer group 10 is provided with a catcher 11 for material to enter.

The bottom opening of the catcher 11 is connected with the top opening of the dryer, the top of each dryer in the drying unit 10 is provided with a first air transmission port and a second air transmission port, the first air transmission ports are connected with a first material conveying blast pipe 40 through a pipeline A, and the second air transmission ports are connected with a second material conveying blast pipe 30 through a pipeline B;

the first material conveying blast pipe 40 and the second material conveying blast pipe 30 are connected with the left opening of the honeycomb runner 23 through the drying treatment system 21, and the right opening of the runner dehumidifier 20 is connected with the regeneration system 22.

Referring to fig. 1, as another embodiment of the present invention, a plurality of air intercepting valves 50 are disposed on both the first air delivery pipe 40 and the second air delivery pipe 30, and the air intercepting valves 50 are disposed on the pipeline a and the pipeline B.

Referring to fig. 1, as another embodiment of the present invention, the drying processing system 21 includes a hopper fan 212, a drying filter 213, a cooler 214, a heater 211, and a roots variable frequency fan 215; wherein, the top opening of the dry filter 213 is connected with the first material conveying and air supplying through a vertical upward pipeline, the right opening of the dry filter 213 is connected with the top right opening of the cooler 214, the top left opening of the cooler 214 is connected with the Roots variable frequency fan 215, the Roots variable frequency fan 215 passes through the honeycomb runner 23 through a section of rightward pipeline C, extends to the right side of the hopper fan 212, and is connected with the hopper fan 212; the hopper fan 212 is connected with the bottom opening of the heater 211; a pipeline D is branched from the connecting pipeline between the drying filter 213 and the cooler 214, and the pipeline D is arranged on the honeycomb rotating wheel 23 in a penetrating way and connected with the pipeline between the Roots variable frequency fan 215 and the heater 211; the top opening of the heater 211 is connected with one end of the second material conveying blast pipe 30; the second material delivery blast pipe 30 is connected to the second air delivery port of the dryer and is provided with an exhaust opening 12 penetrating the dryer and facing the bottom end of the dryer.

Accordingly, the roots variable frequency fan 215 and the hopper fan 212 are started, air enters the pipeline of the drying system 21 of the dehumidifier 20 from the dryer to be filtered and dried, enters the regenerative heater 211 through the honeycomb runner 23 to be subjected to moisture absorption and drying, and finally enters the dryer to be subjected to dehumidification and drying treatment after being heated and dried by the heater 211.

Referring to fig. 1, as another embodiment of the present invention, the exhaust opening 12 is in an inverted triangle shape, thereby increasing the contact area with the material in the dryer.

Referring to fig. 1, as another embodiment of the present invention, the regeneration system 22 includes a regenerative dry filter 213, a regenerative roots variable frequency fan 215 and a regenerative heater 211, a duct E connected to an opening at the top end of the regenerative heater 211 is disposed on the honeycomb rotor 23, an opening at the bottom end of the regenerative heater 211 is connected to the regenerative roots variable frequency fan 215, and the regenerative roots variable frequency fan 215 is connected to the regenerative dry filter 213 rightward.

Referring to fig. 1, as another embodiment of the present invention, a honeycomb rotor 23 includes a sector a, a sector B, and a sector C; the sector A in honeycomb runner 23 is worn to locate by pipeline C, sector B in honeycomb runner 23 is worn to locate by pipeline D, sector C in honeycomb runner 23 is worn to locate by pipeline E, accordingly, regeneration roots's frequency conversion fan 215 starts, the air enters into regeneration system 22's pipeline from regeneration filter, in being pumped regeneration heater 211, then enter into honeycomb runner 23, break away from adsorbed moisture in the honeycomb runner 23 and by the fan discharge, thereby make honeycomb runner 23 resume the moisture absorption function and accomplish regeneration process, honeycomb runner 23 can uninterrupted duty, reach better dehumidification drying effect.

The utility model discloses in, utilize roots's frequency conversion fan 215 control dehumidification drying system's the amount of wind, when using many desiccators, roots's frequency conversion fan 215 can better control dehumidification drying system's the amount of wind, play energy-conserving effect, roots's frequency conversion fan 215 can be according to the quantity of switch desiccator promptly, and the position of charge level indicator is by the output amount of wind of program control frequency conversion fan, reaches energy-conserving effect.

The above description is only for the preferred embodiment of the present invention, and the structure is not limited to the above-mentioned shape, and any modification, equivalent replacement, and improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. The energy-saving dehumidifying and drying system comprises a drying unit, a first material conveying blast pipe, a second material conveying blast pipe and a dehumidifier arranged on the right side of the drying unit, and is characterized in that the dehumidifier comprises a catcher, a honeycomb runner, a drying treatment system and a regeneration system; wherein the content of the first and second substances,

the top end of each drier in the drier set is provided with a catcher for materials to enter;

2. The energy-saving dehumidifying and drying system according to claim 1, wherein: the first material conveying air supply pipe and the second material conveying air supply pipe are respectively provided with a plurality of air intercepting valves, and the air intercepting valves are arranged on the pipeline A and the pipeline B.

3. The energy-saving dehumidifying and drying system according to claim 2, wherein: the drying treatment system comprises a hopper fan, a drying filter, a cooler, a heater and a Roots variable frequency fan;

the top end opening of the drying filter is connected with the first material conveying air supply through a vertical upward pipeline, the right side opening of the drying filter is connected with the top end right side opening of the cooler, the top end left side opening of the cooler is connected with the Roots variable frequency fan, and the Roots variable frequency fan penetrates through the honeycomb rotating wheel through a section of rightward pipeline C to extend to the right side of the hopper fan and is connected with the hopper fan; the hopper fan is connected with the bottom opening of the heater; a pipeline D is branched from a connecting pipeline between the drying filter and the cooler, and the pipeline D is arranged on the honeycomb rotating wheel in a penetrating way and connected to a pipeline between the Roots variable frequency fan and the heater; the top opening of the heater is connected with one end of the second material conveying air supply pipe; the second material conveying air supply pipe is connected with a second air transmission port of the dryer and is provided with an exhaust opening penetrating into the dryer and facing the bottom end of the dryer.

4. The energy-saving dehumidifying and drying system according to claim 3, wherein: the exhaust opening is in an inverted triangle shape.

5. The energy-saving dehumidifying and drying system according to claim 3, wherein: the regeneration system comprises a regeneration dry filter, a regeneration Roots frequency conversion fan and a regeneration heater, a pipeline E connected with an opening at the top end of the regeneration heater is arranged on the honeycomb rotating wheel, an opening at the bottom end of the regeneration heater is connected with the regeneration Roots frequency conversion fan, and the regeneration Roots frequency conversion fan is connected with the regeneration dry filter rightwards.

6. The energy-saving dehumidifying and drying system according to claim 5, wherein: the cell wheel comprises sector a, sector B, and sector C; pipeline C wears to locate sector A in the honeycomb runner, pipeline D wears to locate sector B in the honeycomb runner, pipeline E wears to locate sector C in the honeycomb runner.