CN220475972U - Non-woven fabric static-removing conveying device - Google Patents

Abstract

The utility model provides a non-woven fabric static electricity removing conveying device which comprises a rack, wherein a conveying mechanism is arranged on the rack; the static electricity removing fan is at least provided with one fan for outputting air flow with positive and negative charges; the guide wind nozzle is arranged on the corresponding static eliminating fan; the device is used for adjusting the air outlet width according to the width of the transmitted non-woven fabric. The non-woven fabric static electricity removing conveying device provided by the utility model is provided with the rack, and the rack is provided with the conveying mechanism which can enable the non-woven fabric to be conveyed; the static removing fan is arranged, and the air flow with positive and negative charges can be output to the non-woven fabric above the frame; the static-removing fans are provided with guide air nozzles, the guide air nozzles are arranged on the static-removing fans in a one-to-one correspondence mode, air flows with positive and negative charges can be blown out towards the non-woven fabrics through air outlets of the guide air nozzles, and the air outlet width of the air outlets is adjusted according to the width of the transmitted non-woven fabrics.

Description

Non-woven fabric static-removing conveying device

Technical Field

The utility model belongs to the technical field of non-woven fabric production, and particularly relates to a non-woven fabric static electricity removing conveying device.

Background

The non-woven fabric is also called needled cotton, needled non-woven fabric and the like, is made of polyester fiber and polyester fiber, is made by needling technology, and can be made into different thicknesses, handfeel, hardness and the like. The non-woven fabric has the characteristics of moisture resistance, ventilation, flexibility, portability, flame retardance, no toxicity, no smell, low price, recycling and the like. Can be used in different industries such as sound insulation, heat insulation, electric heater, mask, clothing, medical treatment, filling material, etc.

In the prior art, static electricity is generated on the non-woven fabric in the production process of the non-woven fabric, and the generation of the static electricity is caused by insufficient air humidity; secondly, when the non-woven fabric is produced, the content of the added fiber oil is low. Therefore, when the nonwoven fabric is conveyed by a conveying device, a static electricity removing process is usually performed on the nonwoven fabric during conveyance; in the process of removing static electricity, it is necessary to install static electricity removing equipment on a production line. When the non-woven fabric is produced, according to different use requirements, the situation that the production sizes (mainly the widths) of the non-woven fabric are different can occur; however, the static electricity removing process of the static electricity removing device performed on the conveying device is full coverage, when the size of the non-woven fabric on the conveying device is smaller, the coverage of the static electricity removing device is not matched, resource waste exists, adaptability is poor, and practicality is poor.

Disclosure of Invention

The embodiment of the utility model provides a non-woven fabric static electricity removing conveying device, which aims to solve the problems that the size of non-woven fabric is not matched with the coverage of static electricity removing equipment and the adaptability is poor.

In order to achieve the above purpose, the utility model adopts the following technical scheme: provided is a nonwoven fabric static-removing conveying device, comprising:

the rack is provided with a transmission mechanism for transmitting the non-woven fabrics;

the static electricity removing fans are at least provided with one, and each static electricity removing fan is arranged on the rack and positioned above the non-woven fabric and used for outputting air flow with positive and negative charges; and

the guide air nozzles are at least provided with one, each guide air nozzle is arranged in one-to-one correspondence with each static eliminating fan, and each guide air nozzle is arranged on the corresponding static eliminating fan; every direction tuyere all has the air outlet towards the non-woven fabrics, the direction tuyere is used for adjusting the air outlet width of air outlet according to the non-woven fabrics width of transmission.

In one possible implementation manner, the transmission direction of the non-woven fabric is set as a first direction, and the horizontal direction perpendicular to the first direction is set as a second direction;

the machine frame is provided with a plurality of position adjusting mechanisms, each position adjusting mechanism is arranged at intervals along the first direction and is positioned above the transmission mechanism, and each position adjusting mechanism is arranged with the machine frame in a sliding mode along the first direction.

In one possible implementation, each of the position adjustment mechanisms includes:

the two sliding seats are arranged at intervals along the second direction and are arranged on the rack in a sliding manner;

the sliding rod is arranged along the second direction, and two ends of the sliding rod are respectively connected to the two sliding seats;

wherein, be equipped with in the frame and supply the slide rail that the sliding seat slided.

In one possible implementation manner, a sliding seat is arranged on the sliding rod, and the sliding seat is arranged on the sliding rod in a sliding manner;

wherein, each static eliminating fan is arranged on each sliding seat correspondingly.

In one possible implementation, the static-removing blower is a static fan.

In one possible implementation, the guide tuyere includes:

the body is provided with a ventilation cavity;

the guide plates are arranged at intervals to divide the ventilation cavity into a plurality of guide air channels, one end of each guide air channel is opposite to the non-woven fabric, and the other end of each guide air channel is communicated with a corresponding fan; one end of each guide air duct, which faces the non-woven fabric, is combined to form the air outlet;

the wind shields are arranged in a plurality, are arranged in one-to-one correspondence with the guide air channels, are arranged on the body and are used for controlling the opening and closing of the guide air channels.

In one possible implementation, the transmission mechanism includes a plurality of transmission assemblies, a plurality of the transmission assemblies being disposed horizontally and at intervals along the first direction, each of the transmission assemblies including:

the two fixing seats are arranged at intervals along the second direction;

the transmission wheel is provided with two connecting ends, and the two connecting ends are respectively and rotatably connected to the two fixing seats;

the fixed end of the lifting unit is fixedly arranged on the frame, and the lifting end of the lifting unit vertically extends upwards to be connected to the fixed seat.

In one possible implementation, the lifting unit is a cylinder.

In the implementation mode, compared with the prior art, the machine frame is provided, and the transmission mechanism is arranged on the machine frame and can enable the non-woven fabrics to be transmitted; the static removing fan is arranged, and the air flow with positive and negative charges can be output to the non-woven fabric above the frame; the static-removing fans are provided with guide air nozzles, the guide air nozzles are arranged on the static-removing fans in a one-to-one correspondence mode, air flows with positive and negative charges can be blown out towards the non-woven fabrics through air outlets of the guide air nozzles, and the air outlet width of the air outlets is adjusted according to the width of the transmitted non-woven fabrics.

Drawings

Fig. 1 is a schematic structural diagram of a nonwoven fabric static-removing conveying device according to an embodiment of the present utility model;

fig. 2 is a schematic diagram of the internal structure of a guide tuyere of a non-woven fabric static-removing conveying device according to an embodiment of the present utility model;

reference numerals illustrate:

100. a frame; 110. a transmission mechanism; 111. a fixing seat; 112. a transfer wheel; 113. a lifting unit; 120. a position adjusting mechanism; 121. a sliding seat; 122. a slide bar; 1221. a slide rail; 200. a static electricity removing fan; 300. a guide tuyere; 310. a body; 320. a guide plate; 330. and a wind deflector.

Detailed Description

In order to make the technical problems, technical schemes and beneficial effects to be solved more clear, the utility model is further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the scope of the utility model.

Referring to fig. 1 and fig. 2 together, the present utility model provides a device for transporting nonwoven fabrics to remove static electricity. The non-woven fabric static electricity removing and conveying device comprises a frame 100, and a conveying mechanism 110 for conveying the non-woven fabric is arranged. At least one static eliminating fan 200 is arranged, and each static eliminating fan 200 is arranged on the frame 100 and is positioned above the non-woven fabric and used for outputting air flow with positive and negative charges. The guide wind nozzles 300 are at least provided with one, each guide wind nozzle 300 is arranged in one-to-one correspondence with each static-removing fan 200, and each guide wind nozzle 300 is arranged on the corresponding static-removing fan 200. Each guiding tuyere 300 has an air outlet facing the non-woven fabric, and the guiding tuyere 300 is used for adjusting the air outlet width of the air outlet according to the width of the transmitted non-woven fabric.

Compared with the prior art, the non-woven fabric static-removing conveying device provided by the embodiment is provided with the frame 100, and the frame 100 is provided with the conveying mechanism 110, and the conveying mechanism 110 can enable the non-woven fabric to be conveyed. The static electricity removing fan 200 is arranged above the frame 100, and outputs air flow with positive and negative charges to the non-woven fabric. The static electricity removing fans 200 are provided with the guide air nozzles 300, the guide air nozzles 300 are arranged on the static electricity removing fans 200 in a one-to-one correspondence manner, and air flows with positive and negative charges can be blown out towards the non-woven fabrics through the air outlets of the guide air nozzles 300, and the air outlet width of the air outlets is adjusted according to the width of the transmitted non-woven fabrics.

In some embodiments, the frame 100 may be configured as shown in fig. 1. Referring to fig. 1, the transfer direction of the nonwoven fabric is set as a first direction, and the horizontal direction perpendicular to the first direction is set as a second direction.

The frame 100 is provided with a plurality of position adjusting mechanisms 120, each position adjusting mechanism 120 is arranged at intervals along the first direction and is located above the transmission mechanism 110, and each position adjusting mechanism 120 is arranged with the frame 100 in a sliding manner along the first direction.

The adjustment mechanism can slide on the frame 100 along a first direction, a document sliding rail for the adjustment mechanism to slide can be arranged on the frame 100, the adjustment mechanism can be adjusted at the position on the non-woven fabric, the adjustment mechanism and the non-woven fabric can be adaptively adjusted, and when the partial areas on the non-woven fabric are required to be subjected to important static electricity removal, the distance between the adjustment mechanisms is close, so that the adjustment mechanism is good in adaptability and practicality.

In some embodiments, the position adjustment mechanism 120 may be configured as shown in fig. 1. Referring to fig. 1, each position adjustment mechanism 120 includes: a slide seat 121 and a slide rod 122. The two sliding seats 121 are arranged at intervals along the second direction, and the two sliding seats 121 are arranged on the frame 100 in a sliding manner. The sliding rod 122 is disposed along the second direction, and two ends of the sliding rod 122 are respectively connected to the two sliding seats 121.

The rack 100 is provided with a sliding rail 1221 for sliding the sliding seat 121.

The two sliding seats 121 are disposed on the frame 100 at intervals along the second direction, and can slide along the first direction on the frame 100. The slide bar 122 may be understood as a connection bar, both ends of which are respectively connected to the two slide seats 121. When the two sliding seats 121 slide along the first direction, the sliding rod 122 is driven to slide along the first direction, so that the positions of the adjusting mechanism and the non-woven fabric can be adjusted adaptively, and the device is good in adaptability and practicality.

In some embodiments, the sliding rod 122 may have a structure as shown in fig. 1. Referring to fig. 1, a sliding seat 121 is provided on a sliding rod 122, and the sliding seat 121 is slidably disposed on the sliding rod 122.

Wherein, each static-removing fan 200 is arranged on each corresponding sliding seat 121.

The sliding rod 122 may be provided with a sliding groove, the sliding seat 121 is slidably disposed in the sliding groove, and the sliding seat 121 may slide in the sliding groove along the second direction. The electrostatic fans are arranged on the corresponding sliding seats 121, and the positions of the non-woven fabrics corresponding to the electrostatic fans can be adjusted adaptively through sliding of the sliding seats 121 along the second direction, so that the adaptability is good, and the practicability is good.

In some embodiments, the static electricity removing fan 200 may have a structure as shown in fig. 1. Referring to fig. 1, the static electricity removing fan 200 is an electrostatic fan.

The static fan can output the airflow with positive and negative charges, can neutralize static electricity on the non-woven fabric, and can adjust the size of the blown airflow with positive and negative charges according to the size of the static electricity carried on the non-woven fabric, so that the adaptability is good and the practicability is good.

In some embodiments, the guide tuyere 300 may have a structure as shown in fig. 2. Referring to fig. 2, the guide tuyere 300 includes: body 310, guide plate 320 and wind deflector 330. The body 310 has a vent lumen. The guide plates 320 are provided with a plurality of guide plates 320, and the guide plates 320 are arranged at intervals so as to divide the ventilation cavity into a plurality of guide air channels, one end of each guide air channel is opposite to the non-woven fabric, and the other end of each guide air channel is communicated with a corresponding fan. And one end of each guide air channel facing the non-woven fabric is combined to form an air outlet. The wind shields 330 are provided with a plurality of wind shields 330, each wind shield 330 is arranged in one-to-one correspondence with each guiding air duct, and is arranged on the body 310 for controlling the opening and closing of each guiding air duct.

The ventilation cavity is from the fan to the non-woven fabrics, and the cross section gradual change increases. The guide plates 320 are provided in plurality, and each guide plate 320 is arranged at intervals to divide the ventilation cavity into a plurality of guide air channels, which can be understood that the plurality of guide plates 320 are arranged in the ventilation cavity, three guide plates 320 can be divided into four guide air channels, and four guide plates 320 can be divided into five guide air channels. The wind guard 330 is connected with the body 310 in a sliding manner along the first direction, one end of the wind guard 330 penetrates through the body 310 and then enters into a corresponding guide air duct, a button connected with the wind guard 330 is arranged outside the body 310, and the wind guard 330 is controlled by manually pressing or pulling the button, so that the opening and closing of the guide air duct are controlled.

In some embodiments, the transport mechanism 110 may be configured as shown in fig. 1. Referring to fig. 1, the transfer mechanism 110 includes a plurality of transfer assemblies horizontally and at intervals along a first direction, each transfer assembly including: a fixed base 111, a transmission wheel 112 and a lifting unit 113. The fixing bases 111, the fixing bases 111 are provided with two, and the two fixing bases 111 are arranged at intervals along the second direction. The transmission wheel 112, the transmission wheel 112 has two connection ends, and the two connection ends are respectively rotatably connected to the two fixing bases 111. And a lifting unit 113, wherein a fixed end of the lifting unit 113 is fixedly arranged on the frame 100, and a lifting end of the lifting unit 113 is vertically and upwardly extended and connected to the fixing base 111.

The fixing bases 111 may be disposed at intervals along the second direction. The two connection ends of the transmission wheel 112 are rotatably connected to the two fixing bases 111, respectively. The lifting unit 113 can lift each fixing seat 111 along the vertical direction, and can adjust the lifting height of the transmission mechanism 110, so that the adaptability and the practicability are good.

In some embodiments, the lifting unit 113 may have a structure as shown in fig. 1. Referring to fig. 1, the lifting unit 113 is a cylinder. The cylinder may drive the fixing base 111 to move in a vertical direction. The lifting height of the transmission mechanism 110 can be adjusted according to the static amount carried on the non-woven fabric, so that the applicability is good and the practicability is good.

The foregoing description of the preferred embodiments of the utility model is not intended to be limiting, but rather is intended to cover all modifications, equivalents, and alternatives falling within the spirit and principles of the utility model.

Claims (8)

1. Non-woven fabrics destatics conveyor, its characterized in that includes:

the rack is provided with a transmission mechanism for transmitting the non-woven fabrics;

the static electricity removing fans are at least provided with one, and each static electricity removing fan is arranged on the rack and positioned above the non-woven fabric and used for outputting air flow with positive and negative charges; and

the guide air nozzles are at least provided with one, each guide air nozzle is arranged in one-to-one correspondence with each static eliminating fan, and each guide air nozzle is arranged on the corresponding static eliminating fan; every direction tuyere all has the air outlet towards the non-woven fabrics, the direction tuyere is used for adjusting the air outlet width of air outlet according to the non-woven fabrics width of transmission.

2. The nonwoven fabric destaticizing transport apparatus according to claim 1, wherein the transport direction of the nonwoven fabric is set to a first direction and the horizontal direction perpendicular to the first direction is set to a second direction;

the machine frame is provided with a plurality of position adjusting mechanisms, each position adjusting mechanism is arranged at intervals along the first direction and is positioned above the transmission mechanism, and each position adjusting mechanism is arranged with the machine frame in a sliding mode along the first direction.

3. The nonwoven fabric destaticizing transport apparatus of claim 2 wherein each of said position adjustment mechanisms comprises:

the two sliding seats are arranged at intervals along the second direction and are arranged on the rack in a sliding manner;

the sliding rod is arranged along the second direction, and two ends of the sliding rod are respectively connected to the two sliding seats;

wherein, be equipped with in the frame and supply the slide rail that the sliding seat slided.

4. The non-woven fabric static-removing conveying device according to claim 3, wherein a sliding seat is arranged on the sliding rod, and the sliding seat is arranged on the sliding rod in a sliding manner;

wherein, each static eliminating fan is arranged on each sliding seat correspondingly.

5. The nonwoven fabric static-eliminating conveyor of claim 1, wherein the static-eliminating fan is a static fan.

6. The nonwoven fabric destaticizing transport apparatus of claim 1 wherein said guide tuyere comprises:

the body is provided with a ventilation cavity;

the guide plates are arranged at intervals to divide the ventilation cavity into a plurality of guide air channels, one end of each guide air channel is opposite to the non-woven fabric, and the other end of each guide air channel is communicated with a corresponding fan; one end of each guide air duct, which faces the non-woven fabric, is combined to form the air outlet;

the wind shields are arranged in a plurality, are arranged in one-to-one correspondence with the guide air channels, are arranged on the body and are used for controlling the opening and closing of the guide air channels.

7. The nonwoven fabric destaticizing transport apparatus of claim 2 wherein said transport mechanism comprises a plurality of transport assemblies, a plurality of said transport assemblies being disposed horizontally and at intervals along said first direction, each of said transport assemblies comprising:

the two fixing seats are arranged at intervals along the second direction;

the transmission wheel is provided with two connecting ends, and the two connecting ends are respectively and rotatably connected to the two fixing seats;

the fixed end of the lifting unit is fixedly arranged on the frame, and the lifting end of the lifting unit vertically extends upwards to be connected to the fixed seat.

8. The nonwoven fabric destaticizing transport apparatus of claim 7, wherein said lifting unit is an air cylinder.