CN220776128U - Static electricity removing device - Google Patents

Abstract

The utility model discloses a static electricity removing device, and belongs to the field of static electricity removing. A static-removing device, comprising: the workstation still includes: an elliptical block fixed on the workbench; the feeding cavity is arranged in the elliptical block, and two ends of the elliptical block are respectively provided with a feeding hole and a discharging hole; the first cavity is arranged in the elliptical block, and a plurality of groups of first air nozzles and second air nozzles are arranged between the first cavity and the feeding cavity at equal intervals; the guide surfaces are symmetrically arranged at two ends of the feeding cavity; an air inlet assembly for delivering an electrostatic-depleted gas into the first chamber; the conveying assembly is arranged on the workbench and matched with the feeding cavity; the utility model effectively eliminates static electricity on the glove and effectively prevents the turbulence of gas from influencing the static electricity removing effect.

Description

Static electricity removing device

Technical Field

The utility model relates to the technical field of static electricity removal, in particular to a static electricity removal device.

Background

The glove is a hand warming or labor protection article, the glove has great effect, different functions and gloves made of different materials exist, the glove made of different materials has different functions, the glove is not practical in the first time, the glove is generally used for warming in work or in winter until the next generation, the glove is divided into sewing, knitting, gum dipping and the like according to the manufacturing method, but the glove has a deeper meaning than the glove in the traditional sense, and the glove is quite different from the traditional glove.

The gloves can rub each other in the production process to generate static electricity, and the gloves with static electricity can generate certain potential safety hazards when stacked, so that the static electricity is removed by the static electricity removing device.

The current static electricity removing device is directly provided with an electrostatic fan on the upper side of the glove, the gas with electrons is blown to the glove, and the lower side of the glove is not easy to blow, so that the static electricity removing effect on the lower side is possibly poor, and the static electricity removing device which blows up and down simultaneously is also adopted, but the turbulence of the gas is possibly caused by the blowing, and the static electricity removing effect on the glove is affected.

Disclosure of Invention

The technical problem to be solved by the present utility model is to overcome the deficiencies of the prior art and provide a static electricity removing device which can overcome or at least partially solve the above problems.

In order to achieve the above purpose, the present utility model adopts the following technical scheme:

a static-removing device, comprising: the workstation still includes: an elliptical block fixed on the workbench; the feeding cavity is arranged in the elliptical block, and two ends of the elliptical block are respectively provided with a feeding hole and a discharging hole; the first cavity is arranged in the elliptical block, and a plurality of groups of first air nozzles and second air nozzles are arranged between the first cavity and the feeding cavity at equal intervals; the guide surfaces are symmetrically arranged at two ends of the feeding cavity; an air inlet assembly for delivering an electrostatic-depleted gas into the first chamber; and the conveying assembly is arranged on the workbench and matched with the feeding cavity.

In order to facilitate the glove conveying, preferably, the conveying assembly comprises friction shafts symmetrically rotating on a workbench, a plurality of groups of limiting rings are fixedly connected to the friction shafts at equal intervals, conveying ropes are arranged between the two friction shafts and matched with the limiting rings, a motor is fixedly connected to the workbench, and the output end of the motor is fixedly connected with one of the friction shafts.

In order to be convenient for carry the gas that has the electron, preferably, the subassembly that admits air includes the fixed case of fixing on oval piece, be provided with pump and discharger in the fixed case, the exhaust end fixedly connected with exhaust tube of pump, fixedly connected with blast pipe between the exhaust end of fixed case and the first cavity.

In order to control the flow direction of the gas conveniently, preferably, one side of the elliptic block, which is close to the feeding cavity, is provided with a first arc-shaped surface, and the feeding cavity is in a conical shape.

In order to prevent turbulence of the gas, it is preferable that an excessive surface matching the guide surface is provided in the elliptical block.

In order to facilitate the blowing of gas towards the underside of the glove, preferably a reversing surface matching the transition surface is provided in the oval block.

In order to facilitate downward flow of gas, preferably, the lower end of the elliptical block is symmetrically and fixedly connected with a flow limiting block, and a through groove is arranged between the two flow limiting blocks.

In order to facilitate the gas to flow towards the direction of the discharge port, a flow guide angle is preferably arranged between the flow limiting block and the reversing surface.

In order to facilitate the downward flow of gas, it is preferable that the end of the exhaust pipe remote from the stationary box is disposed on the side facing the feed port.

In order to facilitate the removal of static electricity on the conveying rope, preferably, static electricity removing rods are symmetrically and fixedly connected to the workbench, and the static electricity removing rods are attached to the conveying rope.

Compared with the prior art, the utility model provides the static electricity removing device, which has the following beneficial effects:

1. the static eliminating device has the advantages that the gas with electrons is discharged through the first air jet and the second air jet, static electricity on the upper surface of the glove is eliminated, part of the gas overflows to two sides, flows downwards after contacting with the guide surface and then contacts with the lower surface of the glove, so that static electricity on the glove is effectively eliminated, and the turbulent flow of the gas is effectively prevented to influence the static electricity removing effect.

2. According to the static electricity removing device, the air guided by the guide surface flows downwards and then flows upwards through the transition surface and the reversing surface in sequence, static electricity on the lower surface of the glove is removed, and the air on the lower side of the glove flows from the discharge port to the direction of the feed port through the conical feed cavity, so that turbulence is effectively prevented from being generated by expansion of the air on the lower side of the glove and the air on the upper side of the glove, and further the static electricity removing effect of the glove is effectively improved.

The device has no parts which are the same as or can be realized by adopting the prior art, and the utility model effectively eliminates static electricity on the glove and effectively prevents the turbulence of the gas from influencing the static electricity removing effect.

Drawings

FIG. 1 is a schematic diagram of a static eliminator;

FIG. 2 is a schematic view of an oval block of the static eliminator;

FIG. 3 is a schematic diagram of an oval block of the static eliminator;

FIG. 4 is a schematic cross-sectional view of an oval block of the static discharge device;

fig. 5 is a schematic cross-sectional view of a stationary box of the static eliminator.

In the figure: 1. a work table; 101. a motor; 102. a friction shaft; 103. a limiting ring; 104. a conveying rope; 105. an electrostatic removal bar; 2. an elliptic block; 201. a feed chamber; 202. a first arcuate surface; 203. a guide surface; 204. a transition surface; 205. a reversing surface; 206. a flow-limiting block; 207. a diversion angle; 208. a through groove; 209. a first cavity; 210. a first gas nozzle; 211. a second gas jet; 212. a discharge port; 213. a feed inlet; 3. a fixed box; 301. an exhaust pipe; 302. a pump machine; 303. a discharger; 304. and an exhaust pipe.

Detailed Description

The following description of the embodiments of the present utility model will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present utility model, but not all embodiments.

Example 1: referring to fig. 1, 2, 3, 4 and 5, a static electricity removing apparatus includes: the work bench 1 further comprises: an elliptical block 2 fixed on the workbench 1; a feeding cavity 201 is arranged in the elliptical block 2, and two ends of the elliptical block 2 are respectively provided with a feeding hole 213 and a discharging hole 212; the first cavity 209 is arranged in the elliptical block 2, and a plurality of groups of first air nozzles 210 and second air nozzles 211 are arranged between the first cavity 209 and the feeding cavity 201 at equal intervals; the guide surfaces 203 are symmetrically arranged at two ends of the feeding cavity 201; an air inlet assembly for delivering an electrostatic-dissipative gas into the first chamber 209; and the conveying assembly is arranged on the workbench 1 and matched with the feeding cavity 201, wherein the second air jet ports 211 are obliquely arranged towards two sides.

The conveying assembly comprises friction shafts 102 which symmetrically rotate on the workbench 1, a plurality of groups of limiting rings 103 are fixedly connected to the friction shafts 102 at equal intervals, a conveying rope 104 is arranged between the two friction shafts 102, the conveying rope 104 is matched with the limiting rings 103, a motor 101 is fixedly connected to the workbench 1, and the output end of the motor 101 is fixedly connected with one of the friction shafts 102.

The air inlet assembly comprises a fixed box 3 fixed on the elliptical block 2, a pump 302 and an discharger 303 are arranged in the fixed box 3, an exhaust pipe 301 is fixedly connected to the exhaust end of the pump 302, and an exhaust pipe 304 is fixedly connected between the exhaust end of the fixed box 3 and the first cavity 209.

After the labor protection gloves are produced, the processed gloves are placed on the conveying rope 104, and the motor 101 drives the friction shaft 102 to rotate to convey the gloves, so that the gloves enter from the feed inlet 213 and exit from the discharge outlet 212.

When static electricity is removed, the pump 302 pumps gas, and the pumped gas is contacted with the discharger 303 to carry electric ions, then enters the first cavity 209 through the exhaust pipe 304, and finally is discharged through the first air nozzle 210 and the second air nozzle 211 to remove static electricity on the upper surface of the glove, and part of gas overflows to two sides, flows downwards after contacting with the guide surface 203 and then contacts with the lower surface of the glove, so that static electricity on the glove is effectively removed, and turbulent flow of the gas is effectively prevented to influence the static electricity removal effect.

The conveyance by the conveyor line 104 effectively reduces static electricity generated by the glove rubbing against the conventional conveyor belt.

Example 2: referring to fig. 1, 2, 3, 4 and 5, an electrostatic discharge device is substantially the same as that of embodiment 1, further, a first arc surface 202 is disposed on one side of the elliptical block 2 near the feeding chamber 201, and the feeding chamber 201 is tapered, wherein a cross-sectional area of one end of the feeding chamber 201 near the discharging opening 212 is smaller than a cross-sectional area of one end near the feeding opening 213.

An excessive surface 204 matching the guide surface 203 is provided in the elliptical block 2.

A reversing surface 205 matching the transition surface 204 is provided in the elliptical block 2.

The lower end of the elliptical block 2 is symmetrically and fixedly connected with a current limiting block 206, and a through groove 208 is arranged between the two current limiting blocks 206.

A draft angle 207 is provided between the restrictor block 206 and the reversing surface 205.

The end of the air extraction pipe 301 remote from the stationary box 3 is disposed on the side facing the feed port 213.

The workbench 1 is symmetrically and fixedly connected with static electricity removing rods 105, and the static electricity removing rods 105 are attached to the conveying ropes 104.

The gas guided by the guide surface 203 flows downwards, then flows upwards through the transition surface 204 and the reversing surface 205 in sequence, static electricity on the lower surface of the glove is eliminated, and the gas on the lower side of the glove flows from the discharge hole 212 to the feed hole 213 through the conical feed cavity 201, so that turbulent flow is effectively prevented from being generated by the expansion of the gas on the lower side and the gas on the upper side of the glove, and the static electricity removing effect of the glove is effectively improved.

Through the exhaust pipe 301 arranged on the lower side of the through groove 208 close to the feeding hole 213, the gas in the feeding cavity 201 flows directionally, and the effect of removing static electricity of the hand is effectively improved.

The foregoing is only a preferred embodiment of the present utility model, but the scope of the present utility model is not limited thereto, and any person skilled in the art, who is within the scope of the present utility model, should make equivalent substitutions or modifications according to the technical scheme of the present utility model and the inventive concept thereof, and should be covered by the scope of the present utility model.

Claims (10)

1. A static-removing device, comprising: workstation (1), its characterized in that still includes:

an elliptical block (2) fixed on the workbench (1);

the feeding cavity (201) is arranged in the elliptical block (2), and a feeding hole (213) and a discharging hole (212) are respectively formed at two ends of the elliptical block (2);

the first cavity (209) is arranged in the elliptical block (2), and a plurality of groups of first air nozzles (210) and second air nozzles (211) are arranged between the first cavity (209) and the feeding cavity (201) at equal intervals;

the guide surfaces (203) are symmetrically arranged at two ends of the feeding cavity (201);

an air inlet assembly for delivering an electrostatic-dissipative gas into the first chamber (209);

and the conveying assembly is arranged on the workbench (1) and matched with the feeding cavity (201).

2. The static electricity removing device according to claim 1, wherein the conveying assembly comprises friction shafts (102) symmetrically rotating on the workbench (1), a plurality of groups of limiting rings (103) are fixedly connected to the friction shafts (102) at equal intervals, conveying ropes (104) are arranged between the two friction shafts (102), the conveying ropes (104) are matched with the limiting rings (103), a motor (101) is fixedly connected to the workbench (1), and the output end of the motor (101) is fixedly connected with one of the friction shafts (102).

3. The static electricity removing device according to claim 1, wherein the air inlet assembly comprises a fixed box (3) fixed on the elliptical block (2), a pump (302) and a discharger (303) are arranged in the fixed box (3), an exhaust pipe (301) is fixedly connected to an exhaust end of the pump (302), and an exhaust pipe (304) is fixedly connected between an exhaust end of the fixed box (3) and the first cavity (209).

4. A static-removing device according to claim 1, characterized in that the side of the oblong block (2) close to the feed chamber (201) is provided with a first arcuate surface (202), and the feed chamber (201) is provided with a conical shape.

5. A static-removing device according to claim 3, characterized in that the oval block (2) is provided with a transition surface (204) matching the guiding surface (203).

6. A static-removing device according to claim 5, characterized in that the elliptical block (2) is provided with a reversing surface (205) matching the transition surface (204).

7. The static eliminator as claimed in claim 6, wherein the lower end of the elliptical block (2) is symmetrically and fixedly connected with a current limiting block (206), and a through slot (208) is provided between the two current limiting blocks (206).

8. A static-elimination device according to claim 7, characterized in that a conduction angle (207) is arranged between said current limiting block (206) and the reversing surface (205).

9. A static-removing device according to claim 3, characterized in that the end of the suction tube (301) remote from the stationary box (3) is arranged on the side facing the feed opening (213).

10. The static electricity removing device according to claim 2, wherein static electricity removing rods (105) are symmetrically and fixedly connected to the workbench (1), and the static electricity removing rods (105) are attached to the conveying ropes (104).