CN111411469A

CN111411469A - Energy-saving sock setting machine

Info

Publication number: CN111411469A
Application number: CN202010415830.6A
Authority: CN
Inventors: 李秀华
Original assignee: Taizhou Jiaojiang Zhiya Clothing Co ltd
Current assignee: Taizhou Jiaojiang Zhiya Clothing Co ltd
Priority date: 2020-05-16
Filing date: 2020-05-16
Publication date: 2020-07-14

Abstract

The invention discloses an energy-saving sock setting machine which comprises a rack, wherein an upper shell is fixed on the top surface of a top plate of the rack, a feed port is formed in the left side part of the upper shell, and the feed port is communicated with an inner cavity of the upper shell; go up the shaping on the right side of the roof of casing and have right spiro union through-hole, the connector expert that admits air has the spiro union through-hole, the left side shaping of the roof of going up the casing has the spiro union through-hole of giving vent to anger, it has the exhaust connector to lead to on the spiro union through-hole of giving vent to anger, the expert connects on the exhaust connector has the circulating pipe, the upper end expert of circulating pipe connects the through-hole that has on the left side wall of direction casing, the direction casing is installed on the top surface of the roof of last casing, the center that the interior cavity of direction casing and the middle part shaping of the roof of last casing have leads to. The invention recycles hot steam in the upper shell through discharge, and heats the hot steam again through the heating rod, thereby greatly improving the utilization rate of heat, saving energy and protecting environment.

Description

Energy-saving sock setting machine

Technical Field

The invention relates to the technical field of sock manufacturing equipment, in particular to an energy-saving sock setting machine.

Background

Present socks need carry out the design processing after weaving the completion, and it is that heating high temperature steam carries out the heat setting that it is of current forming machine, however, in the forming machine that present socks were used, it is the high temperature steam heat setting back generally, and steam is direct just to be discharged, and the steam heat this moment is actually still higher, can reuse, and direct emission can produce extravagantly.

Disclosure of Invention

The invention aims to overcome the defects of the prior art and provides an energy-saving sock setting machine which is capable of recycling hot steam in an upper shell through discharge and reheating through a heating rod, so that the utilization rate of heat is greatly improved, and the energy-saving sock setting machine is energy-saving and environment-friendly.

The scheme for solving the technical problems is as follows:

an energy-saving sock setting machine comprises a rack, wherein an upper shell is fixed on the top surface of a top plate of the rack, a feed inlet is formed in the left side of the upper shell, and the feed inlet is communicated with an inner cavity of the upper shell;

the upper shell is provided with a top plate, a top plate and an air inlet connector, wherein the top plate is provided with a right bolt connection through hole, the air inlet connector is connected with a bolt connection through hole, the top plate is provided with an air outlet bolt connection through hole, the air outlet bolt connection through hole is connected with an air exhaust connector, the air exhaust connector is connected with a circulating pipe, and the upper end of the circulating pipe is connected with a water inlet pipe and a water outlet pipe

The guide shell is mounted on the top surface of a top plate of the upper shell, an inner cavity of the guide shell is communicated with a central through groove formed in the middle of the top plate of the upper shell, a circulating motor is fixed on the top surface of the top plate of the guide shell, an output shaft of the circulating motor extends into the guide shell and is fixed with a rotating impeller, and the left side of the rotating impeller faces the through hole.

The right bottom surface of the top plate of the upper shell is fixed with a lower partition plate, the side walls of the lower partition plate are fixed on the front inner side wall and the rear inner side wall of the upper shell, the bottom surface of the lower partition plate is fixed on the top surface of the bottom plate of the upper shell, a plurality of vent holes are formed in the lower partition plate, and the right bolt connection through hole is located on the right side of the lower partition plate.

And a heating connecting plate is fixed on the bottom surface of the middle part of the top plate of the upper shell, and a plurality of heating rods are fixed on the bottom surface of the heating connecting plate.

The heating connecting plate comprises a plurality of transverse plates and a plurality of longitudinal plates, the longitudinal plates are fixed on the bottom surface of the top plate of the upper shell, the transverse plates are fixed on the bottom surfaces of all the longitudinal plates, and the heating rods are fixed on the bottom surfaces of the longitudinal plates.

The left side shaping of the roof of epitheca body has the slot, and the slot aligns from top to bottom with the lower groove that the left part top surface shaping of the bottom plate of epitheca body had, and the door plant plug bush is in slot and lower groove and cover the feed inlet.

The upper portion of the door plate is fixed with a holding portion, and the upper portion of the holding portion extends out of the top surface of the slot.

The bottom surface of the guide shell is fixed with a lower mounting seat, the lower mounting seat is fixed on the top surface of the top plate of the upper shell, an inner cavity of the lower mounting seat is communicated with an inner cavity of the guide shell, and the inner cavity of the lower mounting seat is communicated with the central through groove.

And a plurality of sub-exhaust through holes are formed below the door plate.

The invention has the following outstanding effects: compared with the prior art, the hot steam in the upper shell is discharged for recycling, and the heating rod is used for reheating, so that the utilization rate of heat is greatly improved, and the energy-saving and environment-friendly effects are achieved.

Drawings

FIG. 1 is a schematic structural view of the present invention;

fig. 2 is a partial structural schematic view of the door panel and the upper shell of the present invention.

Detailed Description

Embodiment 1, see fig. 1 to 2, an energy saving sock forming machine includes a frame 10, an upper housing 11 is fixed on a top surface of a top plate of the frame 10, a left side of the upper housing 11 has a feed port 111, and the feed port 111 is communicated with an inner cavity 112 of the upper housing 11;

a right screw joint through hole 12 is formed on the right side of the top plate of the upper shell 11, a screw joint through hole 12 is connected to the air inlet connector 13, an air outlet screw joint through hole 14 is formed on the left side of the top plate of the upper shell 11, an air exhaust connector 15 is connected to the air outlet screw joint through hole 14, a circulating pipe 16 is connected to the air exhaust connector 15, the upper end of the circulating pipe 16 is connected to a through hole 171 formed in the left side wall of the guide shell 17, the guide shell 17 is installed on the top surface of the top plate of the upper shell 11, the inner cavity of the guide shell 17 is communicated with a central through groove 180 formed in the middle of the top plate of the upper shell 11, a circulating motor 18 is fixed on the top surface of the top plate of the guide shell 17, an output shaft of the circulating motor 18 extends into the guide shell 17 and is fixed with a.

Further, a lower partition board 1 is fixed on the bottom surface of the right part of the top plate of the upper shell 11, the side walls of the lower partition board 1 are fixed on the front and rear inner side walls of the upper shell 11, and the side walls of the lower partition board 1

The bottom surface is fixed on the top surface of the bottom plate of the upper shell 11, a plurality of vent holes 2 are formed on the lower partition plate 1, and the right screw joint through hole 12 is positioned on the right side of the lower partition plate 1.

Further, a heating connecting plate 3 is fixed to the bottom surface of the middle portion of the top plate of the upper housing 11, and a plurality of heating rods 4 are fixed to the bottom surface of the heating connecting plate 3.

Further, the heating connection plate 3 includes a plurality of transverse plates 31 and a plurality of longitudinal plates 32, the longitudinal plates 32 are fixed to the bottom surface of the top plate of the upper housing 11, the transverse plates 31 are fixed to the bottom surfaces of all the longitudinal plates 32, and the heating rods 4 are fixed to the bottom surfaces of the longitudinal plates 32.

Further, a slot 113 is formed on the left side of the top plate of the upper housing 11, the slot 113 is aligned with a lower slot 114 formed on the left top surface of the bottom plate of the upper housing 11, and the door plate 19 is inserted into the slot 113 and the lower slot 114 and covers the feeding hole 111.

Further, a holding portion 191 is fixed to an upper portion of the door 19, and an upper portion of the holding portion 191 extends out of a top surface of the slot 113.

Further, a lower mounting seat 179 is fixed on the bottom surface of the guide housing 17, the lower mounting seat 179 is fixed on the top surface of the top plate of the upper housing 11, an inner cavity of the lower mounting seat 179 is communicated with an inner cavity of the guide housing 17, and the inner cavity of the lower mounting seat 179 is communicated with the central through groove 180.

Further, the door panel 19 has a plurality of sub-exhaust through holes 192 formed thereunder.

The upper part of the right side of the door panel 19 is provided with an upper baffle, and the front side wall and the rear side wall of the upper baffle are fixed on the front inner side wall and the rear inner side wall of the upper shell 11 and are positioned right below the air outlet screw joint through hole 14.

When the embodiment is used, the door panel 19 is moved upwards or downwards by manually holding the holding part 191

The device adopts mechanical equipment to clamp and fix the holding part 191 to lift the door panel 19, then the cart with the socks is pushed into the inner cavity 112 of the upper shell 11, then the door panel 19 moves downwards to enable the door panel 19 to be inserted and sleeved in the slot 113 and the lower groove 114 and cover the feeding hole 111, then high-temperature steam or hot gas is introduced into a steam exhaust pipe communicated with the air inlet connector 13 to shape the socks in the inner cavity 112, wherein the steam is uniformly distributed and dispersed through the vent holes 2 on the lower partition plate 1 to be shaped and dried, during drying, the circulating motor 18 operates to enable the rotating impeller 181 to rotate, so that the dried steam of the socks enters the circulating pipe 16 from the exhaust connector 15 and then enters the guide shell 17 and then is blown onto the heating rod 4 through the central through groove 180, and the steam is heated again through the heating rod 4, drying and shaping socks again, it utilizes steam cycle, improve thermal utilization ratio greatly, heating and shaping are effectual, and will follow the below of door plant 19 when atmospheric pressure in the inner chamber 112 is higher and have a plurality of branch exhaust through-holes 192 and discharge, realize the decompression, the conveying capacity of its high-temperature steam that needs can significantly reduce, and the steam reheating that will have the waste heat, its power consumption is also few, the heating is quick, it is effectual to finalize the design stoving, high efficiency, heat utilization ratio is high, energy saving and environmental protection.

Meanwhile, in this embodiment, a top plate of the upper housing 11 is further provided with a temperature sensor, a pressure sensor and the like, which can monitor the temperature and the pressure inside the upper housing 11, the temperature sensor, the pressure sensor, the heating rod 4 and the circulating motor 18 are all electrically connected with a control host through connecting wires, the control host is used for controlling, the control host, the temperature sensor, the pressure sensor, the heating rod 4 and the circulating motor 18 are all commonly known devices, and are not described in detail, and the control host, the temperature sensor and the pressure sensor are also not shown in the attached drawings.

Finally, the above embodiments are only for illustrating the present invention and not for limiting the present invention, and those skilled in the art can make various changes and modifications without departing from the spirit and scope of the present invention, so that all equivalent technical solutions also belong to the scope of the present invention, and the scope of the present invention should be defined by the claims.

Claims

1. The utility model provides an energy-conserving socks forming machine, includes frame (10), its characterized in that: an upper shell (11) is fixed on the top surface of a top plate of the rack (10), a feed port (111) is formed in the left side of the upper shell (11), and the feed port (111) is communicated with an inner cavity (112) of the upper shell (11);

a right screw joint through hole (12) is formed on the right side of the top plate of the upper shell (11), a screw joint through hole (12) is communicated with an air inlet connector (13), an air outlet screw joint through hole (14) is formed on the left side of the top plate of the upper shell (11), an air outlet connector (15) is communicated with the air outlet screw joint through hole (14), a circulating pipe (16) is communicated with the air outlet connector (15), the upper end of the circulating pipe (16) is communicated with a through hole (171) formed in the left side wall of the guide shell (17), the guide shell (17) is installed on the top surface of the top plate of the upper shell (11), the inner cavity of the guide shell (17) is communicated with a central through groove (180) formed in the middle of the top plate of the upper shell (11), a circulating motor (18) is fixed on the top surface of the top plate of the guide shell (17), an output shaft of the circulating motor (18) extends into the guide shell (, the left side of the rotary impeller (181) faces the through hole (171).

2. The energy-saving sock setting machine of claim 1, wherein: the right bottom surface of the top plate of the upper shell (11) is fixed with a lower partition plate (1), the side walls of the lower partition plate (1) are fixed on two inner side walls of the front and the back of the upper shell (11), the bottom surface of the lower partition plate (1) is fixed on the top surface of the bottom plate of the upper shell (11), a plurality of vent holes (2) are formed in the lower partition plate (1), and the right screw connection through hole (12) is located on the right side of the lower partition plate (1).

3. The energy-saving sock setting machine of claim 1, wherein: and a heating connecting plate (3) is fixed on the bottom surface of the middle part of the top plate of the upper shell (11), and a plurality of heating rods (4) are fixed on the bottom surface of the heating connecting plate (3).

4. An energy-saving sock setting machine as claimed in claim 3 wherein: the heating connecting plate (3) comprises a plurality of transverse plates (31) and a plurality of longitudinal plates (32), the longitudinal plates (32) are fixed on the bottom surface of the top plate of the upper shell (11), the transverse plates (31) are fixed on the bottom surfaces of all the longitudinal plates (32), and the heating rods (4) are fixed on the bottom surfaces of the longitudinal plates (32).

5. The energy-saving sock setting machine of claim 1, wherein: a slot (113) is formed in the left side of the top plate of the upper shell (11), the slot (113) is vertically aligned with a lower groove (114) formed in the top surface of the left portion of the bottom plate of the upper shell (11), and the door plate (19) is inserted in the slot (113) and the lower groove (114) and covers the feed port (111).

6. The energy-saving sock setting machine of claim 5, wherein: the upper part of the door panel (19) is fixed with a holding part (191), and the upper part of the holding part (191) extends out of the top surface of the slot (113).

7. The energy-saving sock setting machine of claim 1, wherein: the bottom surface of the guide shell (17) is fixedly provided with a lower mounting seat (179), the lower mounting seat (179) is fixedly arranged on the top surface of the top plate of the upper shell (11), the inner cavity of the lower mounting seat (179) is communicated with the inner cavity of the guide shell (17), and the inner cavity of the lower mounting seat (179) is communicated with the central through groove (180).

8. The energy-saving sock setting machine of claim 5, wherein: the lower part of the door panel (19) is provided with a plurality of sub exhaust through holes (192).