CN111089456A - High-efficient dewatering device is used to textile article - Google Patents
High-efficient dewatering device is used to textile article Download PDFInfo
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- CN111089456A CN111089456A CN201911296174.6A CN201911296174A CN111089456A CN 111089456 A CN111089456 A CN 111089456A CN 201911296174 A CN201911296174 A CN 201911296174A CN 111089456 A CN111089456 A CN 111089456A
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- gear
- wind power
- air flow
- mesh
- hollow shaft
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- 239000004753 textile Substances 0.000 title claims abstract description 26
- 238000006243 chemical reaction Methods 0.000 claims abstract description 254
- 230000018044 dehydration Effects 0.000 claims abstract description 26
- 238000006297 dehydration reaction Methods 0.000 claims abstract description 26
- 238000009434 installation Methods 0.000 claims description 30
- 230000037431 insertion Effects 0.000 claims description 12
- 238000003780 insertion Methods 0.000 claims description 12
- 238000009423 ventilation Methods 0.000 claims description 11
- 238000007789 sealing Methods 0.000 claims description 7
- 239000007788 liquid Substances 0.000 claims description 3
- 230000000149 penetrating effect Effects 0.000 claims description 3
- 239000004744 fabric Substances 0.000 abstract description 4
- 238000010009 beating Methods 0.000 abstract description 2
- 238000007664 blowing Methods 0.000 abstract description 2
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 description 2
- 230000009286 beneficial effect Effects 0.000 description 1
- 230000000694 effects Effects 0.000 description 1
- 238000005516 engineering process Methods 0.000 description 1
- 238000010248 power generation Methods 0.000 description 1
- 238000000926 separation method Methods 0.000 description 1
- 239000000126 substance Substances 0.000 description 1
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Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F26—DRYING
- F26B—DRYING SOLID MATERIALS OR OBJECTS BY REMOVING LIQUID THEREFROM
- F26B5/00—Drying solid materials or objects by processes not involving the application of heat
- F26B5/08—Drying solid materials or objects by processes not involving the application of heat by centrifugal treatment
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F26—DRYING
- F26B—DRYING SOLID MATERIALS OR OBJECTS BY REMOVING LIQUID THEREFROM
- F26B21/00—Arrangements or duct systems, e.g. in combination with pallet boxes, for supplying and controlling air or gases for drying solid materials or objects
- F26B21/06—Controlling, e.g. regulating, parameters of gas supply
- F26B21/12—Velocity of flow; Quantity of flow, e.g. by varying fan speed, by modifying cross flow area
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F26—DRYING
- F26B—DRYING SOLID MATERIALS OR OBJECTS BY REMOVING LIQUID THEREFROM
- F26B25/00—Details of general application not covered by group F26B21/00 or F26B23/00
- F26B25/02—Applications of driving mechanisms, not covered by another subclass
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F26—DRYING
- F26B—DRYING SOLID MATERIALS OR OBJECTS BY REMOVING LIQUID THEREFROM
- F26B3/00—Drying solid materials or objects by processes involving the application of heat
- F26B3/02—Drying solid materials or objects by processes involving the application of heat by convection, i.e. heat being conveyed from a heat source to the materials or objects to be dried by a gas or vapour, e.g. air
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- Engineering & Computer Science (AREA)
- Mechanical Engineering (AREA)
- General Engineering & Computer Science (AREA)
- Life Sciences & Earth Sciences (AREA)
- Microbiology (AREA)
- Health & Medical Sciences (AREA)
- Molecular Biology (AREA)
- Centrifugal Separators (AREA)
Abstract
The invention discloses a high-efficiency dewatering device for textile goods, which comprises a main body shell. The invention utilizes the power source generated by one driving motor, can be used for generating high-pressure gas and performing jet dehydration and centrifugal dehydration functions, so that the textile can perform high-pressure air jet and centrifugal dehydration, thereby realizing the rapid and effective dehydration, effectively and fully utilizing the power of the driving motor, having high utilization rate of kinetic energy and having high efficiency, the device is provided with a thread structure rotary air flow speed control mechanism, can control the discharge speed of air, forms wind power with proper force, and in addition, the device is provided with a hollow shaft type wind power conversion guide mechanism, can convert the position of a space, converts air into wind power for blowing and beating textile fabrics, realizes wind power dehydration, and in addition, the device has a gear mesh type rotation function conversion mechanism, and can improve the rotation speed, thereby realizing strong centrifugal force action.
Description
Technical Field
The invention relates to the technical field of dewatering devices, in particular to a high-efficiency dewatering device for textile goods.
Background
At present, in many places, dewatering devices are needed, and the existing separation devices only convert a power source generated by a driving motor into centrifugal force to perform dewatering treatment of the centrifugal force, so that the efficiency is low, and the effect is not obvious.
Disclosure of Invention
The invention aims to provide an efficient dewatering device for textile articles, which solves the problems in the background technology.
In order to achieve the purpose, the invention provides the following technical scheme: a high-efficiency dehydration device for textile goods comprises a main body shell, wherein a driving motor installation shell is installed on one side of the main body shell, a driving motor is installed inside the driving motor installation shell, opposite turbine installation space and air reserved space are installed inside the main body shell, a motor spindle in the driving motor penetrates through the center of the turbine installation space, a turbine is installed on a spindle body located inside the turbine installation space through the motor spindle, a gear-meshing type rotating function conversion mechanism is installed at the end part of the motor spindle, a main rotating shaft is installed at the center of one end face of the gear-meshing type rotating function conversion mechanism through a main bearing, one end of the main rotating shaft is connected with a hollow shaft type wind power conversion guide mechanism through a main connecting plate, and the hollow shaft type wind power conversion guide mechanism penetrates through the main body shell and the air reserved space, the hollow shaft type wind power conversion guide mechanism is provided with a main sealing ring at one side penetrating through the main body shell, a roller shell is arranged on the shaft body of the hollow shaft type wind power conversion guide mechanism, a dehydration space is arranged at the center in the roller shell, one end of the roller shell is inserted into a sealing cover, the side surface of the roller shell is provided with a plurality of dewatering holes, the main body shell is internally provided with a main exhaust hole communicated with the exhaust end of the turbine installation space and the air reserved space, the middle part of the main exhaust hole is provided with a main part mounting groove structure, the inside of the main part mounting groove structure is provided with a thread structure rotary air flow speed control mechanism, an air inlet port communicated with the external space and the turbine installation space is arranged in the main body shell, the main body shell is internally provided with a main air inlet communicated with the external space and an air inlet port of the turbine installation space.
Further, the screw-structured rotary air flow rate control mechanism includes a housing for the screw-structured rotary air flow rate control mechanism, a center hole for the screw-structured rotary air flow rate control mechanism, a valve rod insertion hole for the screw-structured rotary air flow rate control mechanism, a moving space for the screw-structured rotary air flow rate control mechanism, a moving plate for the screw-structured rotary air flow rate control mechanism, a valve rod for the screw-structured rotary air flow rate control mechanism, a bearing for the screw-structured rotary air flow rate control mechanism, a threaded rod for the screw-structured rotary air flow rate control mechanism, a screw-structured screw for the screw-structured rotary air flow rate control mechanism, and a rotating plate for the screw-structured rotary air flow rate control mechanism; a center hole for the screw structure rotary air flow rate control mechanism is provided at the center of the center hole for the screw structure rotary air flow rate control mechanism at the bottom of the case for the screw structure rotary air flow rate control mechanism, a valve rod insertion hole for the screw structure rotary air flow rate control mechanism is provided at the center of the center hole for the screw structure rotary air flow rate control mechanism at the top of the valve rod insertion hole for the screw structure rotary air flow rate control mechanism, a moving space for the screw structure rotary air flow rate control mechanism is provided at the top of the valve rod insertion hole for the screw structure rotary air flow rate control mechanism, a moving plate for the screw structure rotary air flow rate control mechanism is installed inside the moving space for the screw structure rotary air flow rate control mechanism, a valve rod for the screw structure rotary air flow rate control mechanism is installed inside the valve rod insertion hole for the screw structure rotary, the top of the valve rod for the thread structure rotary air flow speed control mechanism is arranged at the center of the bottom of the moving plate for the thread structure rotary air flow speed control mechanism, the center of the upper surface of the moving plate for the thread structure rotary air flow speed control mechanism is provided with a threaded rod for the thread structure rotary air flow speed control mechanism through a bearing for the thread structure rotary air flow speed control mechanism, the rod body of the threaded rod for the thread structure rotary air flow speed control mechanism is arranged at the center of the top of the shell for the thread structure rotary air flow speed control mechanism through the thread structure for the thread structure rotary air flow speed control mechanism, and a rotating plate for the thread structure rotary air flow speed control mechanism is arranged at the top end of the threaded rod for the thread structure rotary air flow speed control mechanism.
Furthermore, the thread structure for the thread structure rotary air flow speed control mechanism comprises an external thread structure arranged on a threaded rod body for the thread structure rotary air flow speed control mechanism and an internal thread structure arranged on the inner wall of a shell for the structure moving screwing type liquid flow control mechanism.
Further, the housing for the screw structure rotation type air flow velocity control mechanism is installed inside the main part installation space, and the center hole for the screw structure rotation type air flow velocity control mechanism is communicated with the main exhaust hole.
Further, the hollow shaft type wind power conversion guide mechanism comprises a first connecting plate for the hollow shaft type wind power conversion guide mechanism, a first bolt hole for the hollow shaft type wind power conversion guide mechanism, a hollow rod body structure for the hollow shaft type wind power conversion guide mechanism, a second connecting plate for the hollow shaft type wind power conversion guide mechanism, a second bolt hole for the hollow shaft type wind power conversion guide mechanism, a ventilation space for the hollow shaft type wind power conversion guide mechanism, an air inlet hole for the hollow shaft type wind power conversion guide mechanism and an air outlet hole for the hollow shaft type wind power conversion guide mechanism; a plurality of first bolt holes for the hollow shaft type wind power conversion guide mechanism are arranged in the first connecting plate for the hollow shaft type wind power conversion guide mechanism, a hollow shaft body structure for the hollow shaft type wind power conversion guide mechanism with an integrated structure is arranged in the center of one end face of the first connecting plate for the hollow shaft type wind power conversion guide mechanism, a second connecting plate for the hollow shaft type wind power conversion guide mechanism with an integrated structure is arranged on the side face of the middle part of the hollow shaft body structure for the hollow shaft type wind power conversion guide mechanism, a plurality of second bolt holes for the hollow shaft type wind power conversion guide mechanism are arranged in the second connecting plate for the hollow shaft type wind power conversion guide mechanism, and a ventilation space for the hollow shaft type wind power conversion guide mechanism is arranged in the center of the hollow shaft body structure for the hollow shaft type, the hollow rod body structure for the hollow shaft type wind power conversion guide mechanism is positioned between the first connecting plate for the hollow shaft type wind power conversion guide mechanism and the second connecting plate for the hollow shaft type wind power conversion guide mechanism, an air inlet hole for the hollow shaft type wind power conversion guide mechanism is formed in the rod body, the air inlet hole is communicated with the external space and the ventilation space for the hollow shaft type wind power conversion guide mechanism, and an air exhaust hole is formed in the rod body, between one end of the rod body and the second connecting plate for the hollow shaft type wind power conversion guide mechanism, in the hollow rod body structure for the hollow shaft type wind power conversion guide mechanism, the air exhaust hole is communicated with the external space and the ventilation space for the hollow shaft type wind power conversion.
Furthermore, the first connecting plate for the hollow shaft type wind power conversion guide mechanism and the second connecting plate for the hollow shaft type wind power conversion guide mechanism are respectively arranged in the centers of the main connecting plate and one side of the roller shell through bolts.
Further, the air inlet hole for the hollow shaft type wind power conversion guide mechanism and the air outlet hole for the hollow shaft type wind power conversion guide mechanism are respectively positioned in the air reserved space and the dehydration space.
Further, the gear-mesh-type rotational function conversion mechanism includes a hollow housing for the gear-mesh-type rotational function conversion mechanism, a hollow structure for the gear-mesh-type rotational function conversion mechanism, a first rotation shaft for the gear-mesh-type rotational function conversion mechanism, a bearing for the gear-mesh-type rotational function conversion mechanism, a second rotation shaft for the gear-mesh-type rotational function conversion mechanism, a third rotation shaft for the gear-mesh-type rotational function conversion mechanism, a first gear for the gear-mesh-type rotational function conversion mechanism, a second gear for the gear-mesh-type rotational function conversion mechanism, a third gear for the gear-mesh-type rotational function conversion mechanism, and a fourth gear for the gear-mesh-type rotational function conversion mechanism; a hollow structure for the gear-mesh-type rotational function conversion mechanism is provided inside the hollow housing for the gear-mesh-type rotational function conversion mechanism, a first rotating shaft for the gear-mesh-type rotational function conversion mechanism is installed at the center of the bottom of the hollow housing for the gear-mesh-type rotational function conversion mechanism through a bearing for the gear-mesh-type rotational function conversion mechanism, a third rotating shaft for the gear-mesh-type rotational function conversion mechanism is installed at the center of the top of the hollow housing for the gear-mesh-type rotational function conversion mechanism through a bearing for the gear-mesh-type rotational function conversion mechanism, a second rotating shaft for the gear-mesh-type rotational function conversion mechanism is installed at the side of the hollow housing for the gear-mesh-type rotational function conversion mechanism through a bearing for the gear-mesh-type rotational function conversion mechanism, and a second gear for the gear-mesh-type rotational function conversion mechanism and a gear-mesh-type rotational function conversion mechanism are installed on The top end of the first rotating shaft for the gear-meshed rotary function conversion mechanism and the bottom end of the third rotating shaft for the gear-meshed rotary function conversion mechanism are respectively provided with a first gear for the gear-meshed rotary function conversion mechanism and a fourth gear for the gear-meshed rotary function conversion mechanism, the first gear for the gear-meshed rotary function conversion mechanism is meshed with a tooth structure between the second gears for the gear-meshed rotary function conversion mechanism, and the third gear for the gear-meshed rotary function conversion mechanism is meshed with a tooth structure between the fourth gears for the gear-meshed rotary function conversion mechanism.
Further, the structural radius of the first gear reference circle for the gear-mesh-type rotational function conversion mechanism is smaller than the structural radius of the second gear reference circle for the gear-mesh-type rotational function conversion mechanism, the structural radius of the second gear reference circle for the gear-mesh-type rotational function conversion mechanism is larger than the structural radius of the third gear reference circle for the gear-mesh-type rotational function conversion mechanism, and the structural radius of the third gear for the gear-mesh-type rotational function conversion mechanism is smaller than the structural radius of the fourth gear reference circle for the gear-mesh-type rotational function conversion mechanism.
Furthermore, the bottom end of the first rotating shaft for the gear-mesh-type rotating function conversion mechanism and the top end of the third rotating shaft for the gear-mesh-type rotating function conversion mechanism are fixedly connected with the main rotating shaft and the end part of the motor main shaft respectively.
Compared with the prior art, the invention has the beneficial effects that: the invention utilizes the power source generated by one driving motor, can be used for generating high-pressure gas and performing jet dehydration and centrifugal dehydration functions, so that the textile can perform high-pressure air jet and centrifugal dehydration, thereby realizing the rapid and effective dehydration, effectively and fully utilizing the power of the driving motor, having high utilization rate of kinetic energy and having high efficiency, the device is provided with a thread structure rotary air flow speed control mechanism, can control the discharge speed of air, forms wind power with proper force, and in addition, the device is provided with a hollow shaft type wind power conversion guide mechanism, can convert the position of a space, converts air into wind power for blowing and beating textile fabrics, realizes wind power dehydration, and in addition, the device has a gear mesh type rotation function conversion mechanism, and can improve the rotation speed, thereby realizing strong centrifugal force action.
Drawings
FIG. 1 is a schematic view of a full-section of an efficient dewatering device for textile articles according to the present invention;
FIG. 2 is a schematic structural view of a screw-thread structure rotary air flow speed control mechanism in an efficient dewatering device for textile articles according to the present invention;
FIG. 3 is a schematic structural view of a hollow spindle type wind power conversion guide mechanism of the high-efficiency dehydration device for textile articles according to the present invention;
FIG. 4 is a schematic structural view of a gear-mesh type rotating function converting mechanism in the high-efficiency dehydrating apparatus for textile goods according to the present invention;
in the figure: 1, a main body case, 2, a drive motor installation case, 3, a drive motor, 4, a motor spindle, 5, a turbine installation space, 6, a turbine, 7, a main exhaust hole, 8, a main part installation groove structure, 9, a screw structure rotary air flow velocity control mechanism, 91, a screw structure rotary air flow velocity control mechanism case, 92, a screw structure rotary air flow velocity control mechanism center hole, 93, a screw structure rotary air flow velocity control mechanism valve rod insertion hole, 94, a screw structure rotary air flow velocity control mechanism movement space, 95, a screw structure rotary air flow velocity control mechanism moving plate, 96, a screw structure rotary air flow velocity control mechanism valve rod, 97, a screw structure rotary air flow velocity control mechanism bearing, 98, a screw structure rotary air flow velocity control mechanism threaded rod, 99, a screw structure for a screw structure rotary air flow rate control mechanism, 910, a rotary plate for a screw structure rotary air flow rate control mechanism, 11, an air reserved space, 12, a hollow shaft type wind power conversion guide mechanism, 121, a first connecting plate for a hollow shaft type wind power conversion guide mechanism, 122, a first bolt hole for a hollow shaft type wind power conversion guide mechanism, 123, a hollow shaft body structure for a hollow shaft type wind power conversion guide mechanism, 124, a second connecting plate for a hollow shaft type wind power conversion guide mechanism, 125, a second bolt hole for a hollow shaft type wind power conversion guide mechanism, 126, a ventilation space for a hollow shaft type wind power conversion guide mechanism, 127, an air intake hole for a hollow shaft type wind power conversion guide mechanism, 128, an air exhaust hole for a hollow shaft type wind power conversion guide mechanism, 13, a main seal ring, 14, a main connecting plate, a, 15, a gear-mesh-type rotational function conversion mechanism, 151, a hollow housing for a gear-mesh-type rotational function conversion mechanism, 152, a hollow structure for a gear-mesh-type rotational function conversion mechanism, 153, a first rotation shaft for a gear-mesh-type rotational function conversion mechanism, 154, a bearing for a gear-mesh-type rotational function conversion mechanism, 155, a second rotation shaft for a gear-mesh-type rotational function conversion mechanism, 156, a third rotation shaft for a gear-mesh-type rotational function conversion mechanism, 157, a first gear for a gear-mesh-type rotational function conversion mechanism, 158, a second gear for a gear-mesh-type rotational function conversion mechanism, 159, a third gear for a gear-mesh-type rotational function conversion mechanism, 1510, a fourth gear for a gear-mesh-type rotational function conversion mechanism, 16, a main rotation shaft, 17, a drum housing, 18, a dehydration space, 19, a dehydration hole, 20, a sealing cover, a, 21, main air intake.
Detailed Description
The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.
Referring to fig. 1, an embodiment of the present invention: the wind power generation device comprises a main body shell 1, a driving motor installation shell 2 is installed on one side of the main body shell 1, a driving motor 3 is installed inside the driving motor installation shell 2, a turbine installation space 5 and an air reserved space 11 which are opposite are installed inside the main body shell 1, a motor spindle 4 in the driving motor 3 penetrates through the center of the turbine installation space 5, a turbine 6 is installed on a shaft body located inside the turbine installation space 5 of the motor spindle 4, a gear-meshing type rotating function conversion mechanism 15 is installed at the end portion of the motor spindle 4, a main rotating shaft 16 is installed at one end face center of the gear-meshing type rotating function conversion mechanism 15 through a main bearing, one end of the main rotating shaft 16 is connected with a hollow shaft type wind power conversion guide mechanism 12 through a main connecting plate 14, and the hollow shaft type wind power conversion guide mechanism 12 penetrates through the main body shell 1 and the air reserved space 11, the hollow shaft type wind power conversion guide mechanism 12 is provided with a main seal ring 13 on one side penetrating through the main body shell 1, the shaft body of the hollow shaft type wind power conversion guide mechanism 12 is provided with a roller shell 17, the center of the inside of the roller shell 17 is provided with a dehydration space 18, one end of the roller shell 17 is inserted into a seal cover 20, the side surface of the roller shell 17 is provided with a plurality of dehydration holes 19, the inside of the main body shell 1 is provided with a main exhaust hole 7 communicating the exhaust end of the turbine installation space 5 with the air reserved space 11, the middle part of the main exhaust hole 7 is provided with a main part installation groove structure 8, the inside of the main part installation groove structure 8 is provided with a thread structure rotary air flow speed control mechanism 9, the inside of the main body shell 1 is provided with an air inlet port communicating the outside space with the turbine installation space 5, the main body casing 1 is provided with a main air inlet hole 21 inside for communicating the outside space and the air inlet port of the turbine installation space 5.
Referring to fig. 2, the screw-structured rotary air flow rate control mechanism 9 comprises a screw-structured rotary air flow rate control mechanism casing 91, a screw-structured rotary air flow rate control mechanism center hole 92, a screw-structured rotary air flow rate control mechanism stem insertion hole 93, a screw-structured rotary air flow rate control mechanism movement space 94, a screw-structured rotary air flow rate control mechanism movement plate 95, a valve rod 96 for a screw-structured rotary air flow rate control mechanism, a bearing 97 for a screw-structured rotary air flow rate control mechanism, a threaded rod 98 for a screw-structured rotary air flow rate control mechanism, a screw structure 99 for a screw-structured rotary air flow rate control mechanism, and a rotating plate 910 for a screw-structured rotary air flow rate control mechanism; the center of the bottom of the housing 91 for the screw-structured rotary air flow rate control mechanism is provided with a center hole 92 for the screw-structured rotary air flow rate control mechanism, the center of the center hole 92 for the screw-structured rotary air flow rate control mechanism is provided with a valve rod insertion hole 93 for the screw-structured rotary air flow rate control mechanism, the top of the valve rod insertion hole 93 for the screw-structured rotary air flow rate control mechanism is provided with a moving space 94 for the screw-structured rotary air flow rate control mechanism, the inside of the moving space 94 for the screw-structured rotary air flow rate control mechanism is provided with a moving plate 95 for the screw-structured rotary air flow rate control mechanism, and the inside of the valve rod insertion hole 93 for the screw-structured rotary air flow rate control mechanism is provided with a screw-structured rotary air flow rate control mechanism With the valve rod 96, the top of the screw-structured rotary air flow rate control mechanism-use valve rod 96 is mounted at the center of the bottom of the screw-structured rotary air flow rate control mechanism-use moving plate 95, a screw rod 98 for screw structure rotary air flow rate control mechanism is installed at the center of the upper surface of the moving plate 95 for screw structure rotary air flow rate control mechanism through a bearing 97 for screw structure rotary air flow rate control mechanism, the rod body of the threaded rod 98 for the screw-structured rotary air flow rate control mechanism is mounted at the center of the top of the housing 91 for the screw-structured rotary air flow rate control mechanism through the screw-structured rotary air flow rate control mechanism screw 99, a rotating plate 910 for a screw-structured rotary air flow rate control mechanism is mounted on the top end of the screw rod 98 for a screw-structured rotary air flow rate control mechanism; the thread structure 99 for the thread structure rotary air flow speed control mechanism comprises an external thread structure arranged on the rod body of the threaded rod 98 for the thread structure rotary air flow speed control mechanism and an internal thread structure arranged on the inner wall of the outer shell 91 for the structure moving screwing type liquid flow control mechanism; the housing 91 for the screw-structured rotary air flow rate control mechanism is mounted inside the main part mounting space 8, and the center hole 92 for the screw-structured rotary air flow rate control mechanism communicates with the main exhaust hole 7.
Referring to fig. 3, the hollow shaft type wind power conversion guiding mechanism 12 includes a first connecting plate 121 for a hollow shaft type wind power conversion guiding mechanism, a first bolt hole 122 for a hollow shaft type wind power conversion guiding mechanism, a hollow rod structure 123 for a hollow shaft type wind power conversion guiding mechanism, a second connecting plate 124 for a hollow shaft type wind power conversion guiding mechanism, a second bolt hole 125 for a hollow shaft type wind power conversion guiding mechanism, a ventilation space 126 for a hollow shaft type wind power conversion guiding mechanism, an air inlet hole 127 for a hollow shaft type wind power conversion guiding mechanism, and an air outlet hole 128 for a hollow shaft type wind power conversion guiding mechanism; a plurality of first bolt holes 122 for the hollow shaft type wind power conversion guide mechanism are arranged in the first connecting plate 121 for the hollow shaft type wind power conversion guide mechanism, a hollow shaft body structure 123 for the hollow shaft type wind power conversion guide mechanism of an integrated structure is arranged in the center of one end face of the first connecting plate 121 for the hollow shaft type wind power conversion guide mechanism, a second connecting plate 124 for the hollow shaft type wind power conversion guide mechanism of an integrated structure is arranged on the side face of the middle part of the hollow shaft body structure 123 for the hollow shaft type wind power conversion guide mechanism, a plurality of second bolt holes 125 for the hollow shaft type wind power conversion guide mechanism are arranged in the second connecting plate 124 for the hollow shaft type wind power conversion guide mechanism, and a ventilation space 126 for the hollow shaft type wind power conversion guide mechanism is arranged in the center of the hollow shaft body structure 123 for the hollow shaft type, the hollow rod body structure 123 for the hollow shaft type wind power conversion guide mechanism is provided with a hollow shaft type wind power conversion guide mechanism air inlet hole 127 which is positioned on the rod body between the first connecting plate 121 for the hollow shaft type wind power conversion guide mechanism and the second connecting plate 124 for the hollow shaft type wind power conversion guide mechanism and is used for communicating an external space with a hollow shaft type wind power conversion guide mechanism air vent space 126, and the hollow rod body structure 123 for the hollow shaft type wind power conversion guide mechanism is provided with a hollow shaft type wind power conversion guide mechanism air vent hole 128 which is positioned on the rod body between one end of the hollow rod body structure 123 and the second connecting plate 124 for the hollow shaft type wind power conversion guide mechanism and is used for communicating the external space with the hollow shaft type wind power conversion guide; the first connecting plate 121 for the hollow shaft type wind power conversion guide mechanism and the second connecting plate 124 for the hollow shaft type wind power conversion guide mechanism are respectively arranged in the centers of one sides of the main connecting plate 14 and the roller shell 17 through bolts; the air inlet 127 for the hollow shaft type wind power conversion guide mechanism and the air outlet 128 for the hollow shaft type wind power conversion guide mechanism are respectively positioned in the air reserving space 11 and the dehydration space 18.
Referring to fig. 4, the gear-mesh-type rotational function conversion mechanism 15 includes a hollow housing 151 for a gear-mesh-type rotational function conversion mechanism, a hollow structure 152 for a gear-mesh-type rotational function conversion mechanism, a first rotational shaft 153 for a gear-mesh-type rotational function conversion mechanism, a bearing 154 for a gear-mesh-type rotational function conversion mechanism, a second rotational shaft 155 for a gear-mesh-type rotational function conversion mechanism, a third rotational shaft 157 for a gear-mesh-type rotational function conversion mechanism, a first gear 158 for a gear-mesh-type rotational function conversion mechanism, a second gear 159 for a gear-mesh-type rotational function conversion mechanism, a third gear 1510 for a gear-mesh-type rotational function conversion mechanism, and a fourth gear 1511 for a gear-mesh-type rotational function conversion mechanism; a hollow structure 152 for a gear-mesh-type rotational function conversion mechanism is provided inside the hollow housing 151 for a gear-mesh-type rotational function conversion mechanism, a first rotation shaft 153 for a gear-mesh-type rotational function conversion mechanism is attached to the center of the bottom of the hollow housing 151 for a gear-mesh-type rotational function conversion mechanism through a bearing 154 for a gear-mesh-type rotational function conversion mechanism, a third rotation shaft 157 for a gear-mesh-type rotational function conversion mechanism is attached to the center of the top of the hollow housing 151 for a gear-mesh-type rotational function conversion mechanism through a bearing 154 for a gear-mesh-type rotational function conversion mechanism, a second rotation shaft 155 for a gear-mesh-type rotational function conversion mechanism is attached to the side of the hollow housing 151 for a gear-mesh-type rotational function conversion mechanism through a bearing 154 for a gear-mesh-type rotational function conversion mechanism, and a shaft body of the second rotation shaft 155 for a gear-mesh-type rotational function conversion mechanism is A second gear 159 for chemical conversion mechanism and a third gear 1510 for gear-mesh-type rotational function conversion mechanism, the first gear 158 for gear-mesh-type rotational function conversion mechanism and the fourth gear 1511 for gear-mesh-type rotational function conversion mechanism being attached to the top end of the first rotation shaft 153 for gear-mesh-type rotational function conversion mechanism and the bottom end of the third rotation shaft 157 for gear-mesh-type rotational function conversion mechanism, respectively, and the first gear 158 for gear-mesh-type rotational function conversion mechanism and the second gear 159 for gear-mesh-type rotational function conversion mechanism are meshed with each other in tooth structure, and the third gear 1510 for gear-mesh-type rotational function conversion mechanism and the fourth gear 1511 for gear-mesh-type rotational function conversion mechanism are meshed with each other in tooth structure; the structural radius of the reference circle of the first gear 158 for the gear-mesh-type rotational function conversion mechanism is smaller than the structural radius of the reference circle of the second gear 159 for the gear-mesh-type rotational function conversion mechanism, the structural radius of the reference circle of the second gear 159 for the gear-mesh-type rotational function conversion mechanism is larger than the structural radius of the reference circle of the third gear 1510 for the gear-mesh-type rotational function conversion mechanism, and the structural radius of the reference circle of the fourth gear 1511 for the gear-mesh-type rotational function conversion mechanism is smaller than the structural radius of the reference circle of the third gear 1510 for the gear-mesh-type rotational function conversion mechanism; the bottom end of the first rotating shaft 153 for the gear-mesh-type rotating function converting mechanism and the top end of the third rotating shaft 157 for the gear-mesh-type rotating function converting mechanism are fixedly connected to the main rotating shaft 16 and the end of the motor spindle 4, respectively.
The specific use mode is as follows: during the operation of the invention, the sealing cover 20 is opened, then the textile fabric is stuffed into the dehydration space 18, then the sealing cover 20 is closed, the driving motor 3 is opened, the discharge pressure of the gas is controlled, at the moment, the high-pressure air carries out wind power dehydration on the textile fabric under the linkage action of the components, simultaneously, the dehydration function can be carried out under the action of the centrifugal force, and the water is discharged through the water discharge hole 19, thus realizing the dual-function dehydration function.
It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof. The present embodiments are therefore to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.
Claims (10)
1. An efficient dewatering device for textile goods, comprising a main body shell (1), characterized in that: a driving motor installation shell (2) is installed on one side of the main body shell (1), a driving motor (3) is installed inside the driving motor installation shell (2), a turbine installation space (5) and an air reserved space (11) which are opposite are installed inside the main body shell (1), a motor spindle (4) in the driving motor (3) penetrates through the center of the turbine installation space (5), a turbine (6) is installed on a spindle body located inside the turbine installation space (5) on the motor spindle (4), a gear-meshed type rotating function conversion mechanism (15) is installed at the end part of the motor spindle (4), a main rotating shaft (16) is installed at the center of one end face of the gear-meshed type rotating function conversion mechanism (15) through a main bearing, and one end of the main rotating shaft (16) is connected with a hollow shaft type wind power conversion guide mechanism (12) through a main connecting plate (14), the hollow shaft type wind power conversion guide mechanism (12) penetrates through the main body shell (1) and the air reserved space (11), a main sealing ring (13) is installed on one side penetrating through the position of the main body shell (1) of the hollow shaft type wind power conversion guide mechanism (12), a roller shell (17) is installed on a shaft body of the hollow shaft type wind power conversion guide mechanism (12), a dehydration space (18) is arranged in the center of the interior of the roller shell (17), a sealing cover (20) is inserted into one end of the roller shell (17), a plurality of dehydration holes (19) are formed in the side face of the roller shell (17), a main exhaust hole (7) communicating the exhaust end of the turbine installation space (5) and the air reserved space (11) is formed in the interior of the main body shell (1), and a main component installation groove structure (8) is arranged in the middle of the main exhaust hole (7), the main part mounting groove structure (8) is internally provided with a thread structure rotary air flow speed control mechanism (9), the inside of the main body shell (1) is provided with an air inlet port communicated with the external space and the turbine mounting space (5), and the inside of the main body shell (1) is provided with a main air inlet hole (21) communicated with the external space and the air inlet port of the turbine mounting space (5).
2. A high efficiency dewatering apparatus for textile articles as claimed in claim 1, characterised in that: the thread structure rotary air flow speed control mechanism (9) comprises a shell (91) for the thread structure rotary air flow speed control mechanism, a central hole (92) for the thread structure rotary air flow speed control mechanism, a valve rod inserting hole (93) for the thread structure rotary air flow speed control mechanism, a moving space (94) for the thread structure rotary air flow speed control mechanism and a moving plate (95) for the thread structure rotary air flow speed control mechanism, a valve rod (96) for a screw-structured rotary air flow rate control mechanism, a bearing (97) for a screw-structured rotary air flow rate control mechanism, a threaded rod (98) for a screw-structured rotary air flow rate control mechanism, a screw-structured rotary air flow rate control mechanism screw structure (99) and a screw plate (910) for a screw-structured rotary air flow rate control mechanism; a center hole (92) for the screw structure rotary air flow velocity control mechanism is arranged at the center of the center hole (92) for the screw structure rotary air flow velocity control mechanism at the bottom of the housing (91) for the screw structure rotary air flow velocity control mechanism, a valve rod insertion hole (93) for the screw structure rotary air flow velocity control mechanism is arranged at the center of the center hole (92) for the screw structure rotary air flow velocity control mechanism, a moving space (94) for the screw structure rotary air flow velocity control mechanism is arranged at the top of the valve rod insertion hole (93) for the screw structure rotary air flow velocity control mechanism, and a moving plate (95) for the screw structure rotary air flow velocity control mechanism is arranged inside the moving space (94) for the screw structure rotary air flow velocity control mechanism, the valve rod (96) for the thread structure rotation type air flow velocity control mechanism is internally provided with a thread structure rotation type air flow velocity control mechanism through a valve rod inserting hole (93) for the thread structure rotation type air flow velocity control mechanism, the top of the valve rod (96) for the thread structure rotation type air flow velocity control mechanism is arranged at the bottom center of a moving plate (95) for the thread structure rotation type air flow velocity control mechanism, the upper surface center of the moving plate (95) for the thread structure rotation type air flow velocity control mechanism is provided with a thread rod (98) for the thread structure rotation type air flow velocity control mechanism through a bearing (97) for the thread structure rotation type air flow velocity control mechanism, the rod body of the thread rod (98) for the thread structure rotation type air flow velocity control mechanism is arranged at the top center of a shell (91) for the thread structure rotation type air flow velocity control mechanism through a thread structure (99) for the And a rotating plate (910) for the screw-structured rotary air flow rate control mechanism is attached to the tip of the screw rod (98) for the screw-structured rotary air flow rate control mechanism.
3. A high efficiency dewatering apparatus for textile articles as claimed in claim 2, characterised in that: the thread structure (99) for the thread structure rotary air flow speed control mechanism comprises an external thread structure arranged on a threaded rod (98) body for the thread structure rotary air flow speed control mechanism and an internal thread structure arranged on the inner wall of a shell (91) for the structure moving screwing type liquid flow control mechanism.
4. A high efficiency dewatering apparatus for textile articles as claimed in claim 2, characterised in that: the housing (91) for the screw-structured rotary air flow rate control mechanism is installed inside the main part installation space (8), and the center hole (92) for the screw-structured rotary air flow rate control mechanism communicates with the main exhaust hole (7).
5. A high efficiency dewatering apparatus for textile articles as claimed in claim 1, characterised in that: the hollow shaft type wind power conversion guide mechanism (12) comprises a first connecting plate (121) for the hollow shaft type wind power conversion guide mechanism, a first bolt hole (122) for the hollow shaft type wind power conversion guide mechanism, a hollow shaft body structure (123) for the hollow shaft type wind power conversion guide mechanism, a second connecting plate (124) for the hollow shaft type wind power conversion guide mechanism, a second bolt hole (125) for the hollow shaft type wind power conversion guide mechanism, a ventilation space (126) for the hollow shaft type wind power conversion guide mechanism, an air inlet hole (127) for the hollow shaft type wind power conversion guide mechanism and an exhaust hole (128) for the hollow shaft type wind power conversion guide mechanism; a plurality of first bolt holes (122) for the hollow shaft type wind power conversion guide mechanism are arranged in a first connecting plate (121) for the hollow shaft type wind power conversion guide mechanism, a hollow shaft body structure (123) for the hollow shaft type wind power conversion guide mechanism is arranged in the center of one end face of the first connecting plate (121) for the hollow shaft type wind power conversion guide mechanism, a second connecting plate (124) for the hollow shaft type wind power conversion guide mechanism is arranged on the side face of the middle part of the hollow shaft body structure (123) for the hollow shaft type wind power conversion guide mechanism, a plurality of second bolt holes (125) for the hollow shaft type wind power conversion guide mechanism are arranged in the second connecting plate (124) for the hollow shaft type wind power conversion guide mechanism, and a ventilation space (126) for the hollow shaft type wind power conversion guide mechanism is arranged in the center of the hollow shaft body structure (123) for the hollow shaft type wind power conversion, the hollow rod body structure (123) for the hollow shaft type wind power conversion guide mechanism is provided with an air inlet hole (127) for the hollow shaft type wind power conversion guide mechanism, which is used for communicating an external space with an air ventilation space (126) for the hollow shaft type wind power conversion guide mechanism, on a rod body positioned between the first connecting plate (121) for the hollow shaft type wind power conversion guide mechanism and the second connecting plate (124) for the hollow shaft type wind power conversion guide mechanism, and the hollow rod body structure (123) for the hollow shaft type wind power conversion guide mechanism is provided with an air outlet hole (128) for the hollow shaft type wind power conversion guide mechanism, which is used for communicating the external space with the air ventilation space (126) for the hollow shaft type wind power conversion guide mechanism, on a rod body positioned between one end of the hollow rod body structure (123) for.
6. An efficient dewatering apparatus for textile articles as claimed in claim 5, characterised in that: the first connecting plate (121) for the hollow shaft type wind power conversion guide mechanism and the second connecting plate (124) for the hollow shaft type wind power conversion guide mechanism are respectively installed in the centers of one sides of the main connecting plate (14) and the roller shell (17) through bolts.
7. An efficient dewatering apparatus for textile articles as claimed in claim 5, characterised in that: and the air inlet (127) for the hollow shaft type wind power conversion guide mechanism and the air outlet (128) for the hollow shaft type wind power conversion guide mechanism are respectively positioned in the air reserved space (11) and the dehydration space (18).
8. A high efficiency dewatering apparatus for textile articles as claimed in claim 1, characterised in that: the gear-mesh-type rotational function conversion mechanism (15) comprises a hollow housing (151) for a gear-mesh-type rotational function conversion mechanism, a hollow structure (152) for a gear-mesh-type rotational function conversion mechanism, a first rotating shaft (153) for a gear-mesh-type rotational function conversion mechanism, a bearing (154) for a gear-mesh-type rotational function conversion mechanism, a second rotating shaft (155) for a gear-mesh-type rotational function conversion mechanism, a third rotating shaft (157) for a gear-mesh-type rotational function conversion mechanism, a first gear (158) for a gear-mesh-type rotational function conversion mechanism, a second gear (159) for a gear-mesh-type rotational function conversion mechanism, a third gear (1510) for a gear-mesh-type rotational function conversion mechanism, and a fourth gear (1511) for a gear-mesh-type rotational function conversion mechanism; a hollow structure (152) for the gear-mesh-type rotational function conversion mechanism is provided inside the hollow housing (151) for the gear-mesh-type rotational function conversion mechanism, a first rotating shaft (153) for the gear-mesh-type rotational function conversion mechanism is installed at the center of the bottom of the hollow housing (151) for the gear-mesh-type rotational function conversion mechanism through a bearing (154) for the gear-mesh-type rotational function conversion mechanism, a third rotating shaft (157) for the gear-mesh-type rotational function conversion mechanism is installed at the center of the top of the hollow housing (151) for the gear-mesh-type rotational function conversion mechanism through a bearing (154) for the gear-mesh-type rotational function conversion mechanism, a second rotating shaft (155) for the gear-mesh-type rotational function conversion mechanism is installed at the side of the hollow housing (151) for the gear-mesh-type rotational function conversion mechanism through a bearing (154) for the gear-mesh-type, a second gear (159) for a gear mesh type rotational function conversion mechanism and a third gear (1510) for a gear mesh type rotational function conversion mechanism are mounted on a shaft body of the second rotational shaft (155) for a gear mesh type rotational function conversion mechanism, a first gear (158) for a gear mesh type rotational function conversion mechanism and a fourth gear (1511) for a gear mesh type rotational function conversion mechanism are mounted on a top end of the first rotational shaft (153) for a gear mesh type rotational function conversion mechanism and a bottom end of the third rotational shaft (157) for a gear mesh type rotational function conversion mechanism, respectively, and a tooth structure between the first gear (158) for a gear mesh type rotational function conversion mechanism and the second gear (159) for a gear mesh type rotational function conversion mechanism is meshed, a tooth structure between the third gear (1510) for a gear mesh type rotational function conversion mechanism and the fourth gear (1511) for a gear mesh type rotational function conversion mechanism is meshed And (6) mixing.
9. A high efficiency dewatering apparatus for textile articles as claimed in claim 8, characterised in that: the structure radius of the reference circle of the first gear (158) for the gear mesh type rotational function conversion mechanism is smaller than the structure radius of the reference circle of the second gear (159) for the gear mesh type rotational function conversion mechanism, the structure radius of the reference circle of the second gear (159) for the gear mesh type rotational function conversion mechanism is larger than the structure radius of the reference circle of the third gear (1510) for the gear mesh type rotational function conversion mechanism, and the structure radius of the reference circle of the fourth gear (1511) for the gear mesh type rotational function conversion mechanism is smaller than the structure radius of the reference circle of the third gear (1510) for the gear mesh type rotational function conversion mechanism.
10. A high efficiency dewatering apparatus for textile articles as claimed in claim 8, characterised in that: the bottom end of the first rotating shaft (153) for the gear mesh type rotating function conversion mechanism and the top end of the third rotating shaft (157) for the gear mesh type rotating function conversion mechanism are fixedly connected with the main rotating shaft (16) and the end part of the motor spindle (4) respectively.
Priority Applications (1)
| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201911296174.6A CN111089456B (en) | 2019-12-16 | 2019-12-16 | High-efficient dewatering device is used to textile article |
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| Application Number | Priority Date | Filing Date | Title |
|---|---|---|---|
| CN201911296174.6A CN111089456B (en) | 2019-12-16 | 2019-12-16 | High-efficient dewatering device is used to textile article |
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| Publication Number | Publication Date |
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| CN111089456A true CN111089456A (en) | 2020-05-01 |
| CN111089456B CN111089456B (en) | 2021-08-10 |
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Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN114457537A (en) * | 2021-12-20 | 2022-05-10 | 际华三五零九纺织有限公司 | Spinning fiber dehydrator capable of facilitating loading and unloading and adjusting dryness |
Citations (4)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| KR200482032Y1 (en) * | 2014-02-14 | 2016-12-07 | 그레이트-이글 테크놀로지스 코., 엘티디. | Spin-dryer |
| CN207299731U (en) * | 2017-10-16 | 2018-05-01 | 赣州市同兴达电子科技有限公司 | A kind of efficient panel drying equipment |
| CN108506573A (en) * | 2018-04-19 | 2018-09-07 | 杨国亭 | Large-scale pipeline used in a kind of Architecture Field places holder |
| CN209326252U (en) * | 2018-11-19 | 2019-08-30 | 江苏洁润管业有限公司 | A kind of plastic grains drying hopper drying machine |
-
2019
- 2019-12-16 CN CN201911296174.6A patent/CN111089456B/en active Active
Patent Citations (5)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| KR200482032Y1 (en) * | 2014-02-14 | 2016-12-07 | 그레이트-이글 테크놀로지스 코., 엘티디. | Spin-dryer |
| CN207299731U (en) * | 2017-10-16 | 2018-05-01 | 赣州市同兴达电子科技有限公司 | A kind of efficient panel drying equipment |
| CN108506573A (en) * | 2018-04-19 | 2018-09-07 | 杨国亭 | Large-scale pipeline used in a kind of Architecture Field places holder |
| CN108506573B (en) * | 2018-04-19 | 2020-06-19 | 马鞍山楚兴市政设施有限公司 | Large-scale pipeline placing support for construction site |
| CN209326252U (en) * | 2018-11-19 | 2019-08-30 | 江苏洁润管业有限公司 | A kind of plastic grains drying hopper drying machine |
Cited By (1)
| Publication number | Priority date | Publication date | Assignee | Title |
|---|---|---|---|---|
| CN114457537A (en) * | 2021-12-20 | 2022-05-10 | 际华三五零九纺织有限公司 | Spinning fiber dehydrator capable of facilitating loading and unloading and adjusting dryness |
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| CN111089456B (en) | 2021-08-10 |
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Effective date of registration: 20210722 Address after: 242000 north of Jingdu Avenue, cross Economic Development Zone, Langxi County, Xuancheng City, Anhui Province Applicant after: Anhui Husheng Textile Technology Co.,Ltd. Address before: No. 37, East Group, mujiakou village, Zhangfang Town, Fangshan District, Beijing 102488 Applicant before: Chen Fengzhi |
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