CN215031176U - Polyester chip screening device for producing polyester industrial yarns - Google Patents

Abstract

The utility model discloses a polyester chip screening device for producing polyester industrial yarns, which comprises a shell, a vibration motor and a driving component which are arranged outside the shell, a first sieve plate and a material guide plate which are arranged inside the shell, first receipts feed bin and second receipts feed bin, first sieve and stock guide all rotationally are connected with the shell, first sieve mesh has been seted up on the first sieve, first receipts feed bin and second receive the relative both sides that set up and lie in the stock guide below in feed guide, drive assembly is including rotationally locating the gear on the shell, with gear engagement's rack and connect the second sieve on the rack, the lateral wall of shell is run through to second sieve slidable, the second sieve mesh has been seted up on the second sieve, second sieve mesh and first sieve mesh one-to-one, the aperture of second sieve mesh is less than the aperture of first sieve mesh, and make the coaxial setting of second sieve mesh and the first sieve mesh that corresponds. The utility model discloses a sieving mechanism can select too big or the polyester section of undersize in the raw materials, has promoted the finished product performance.

Description

Polyester chip screening device for producing polyester industrial yarns

Technical Field

The utility model relates to a polyester industrial yarn production technical field especially relates to a polyester section sieving mechanism for producing polyester industrial yarn.

Background

The polyester chip is a main raw material for producing the polyester industrial yarn, and a series of operations such as high-temperature heating, tackifying, extruding and the like need to be carried out on the polyester chip during production, so that the requirement on the raw material of the polyester chip is high, and the polyester chip which is too large or too small doped in the raw material can cause poor drafting elastic performance of the produced polyester industrial yarn, thereby influencing the strength of the product. Therefore, a device capable of screening the size of the polyester chips is needed to improve the performance of the finished polyester industrial yarn.

SUMMERY OF THE UTILITY MODEL

The utility model discloses the technical problem that will solve is: in order to overcome the defects in the prior art, the polyester chip screening device for producing the polyester industrial yarns, which can screen the oversize and undersize polyester industrial yarns, is provided.

The utility model provides a technical scheme that its technical problem adopted is: a polyester chip screening device for producing polyester industrial yarns comprises a shell, a vibrating motor and a driving assembly which are arranged outside the shell, and a first sieve plate, a material guide plate, a first material receiving bin and a second material receiving bin which are arranged inside the shell, wherein the first sieve plate and the material guide plate are both rotatably connected with the shell, the first sieve plate is positioned above the material guide plate, a first sieve hole is formed in the first sieve plate, the first material receiving bin and the second material receiving bin are oppositely arranged and positioned at two sides below the material guide plate, the driving assembly comprises a gear rotatably arranged on the shell, a rack meshed with the gear and a second sieve plate connected on the rack, the second sieve plate slidably penetrates through the side wall of the shell, a second sieve hole is formed in the second sieve plate, and the second sieve hole is in one-to-one correspondence with the first sieve hole, the aperture of the second sieve hole is smaller than that of the first sieve hole, the second sieve plate is positioned above the first sieve plate and can be attached to the first sieve plate, and the second sieve hole is coaxial with the corresponding first sieve hole.

Further, the shell includes that inside is hollow structure's first casing and second casing, the second casing is connected the lower extreme of first casing, first sieve is rotationally installed in the first casing, vibrating motor installs on the outer wall of first casing, the stock guide is rotationally installed in the second casing, first material receiving storehouse with second material receiving storehouse all sets up in the second casing.

Furthermore, a sliding groove is formed in the side wall of the first shell and penetrates through the inner side wall and the outer side wall of the first shell, and the second sieve plate is connected with the sliding groove in a sliding fit mode.

Further, a supporting seat is installed on the outer wall of the second shell, the gear is rotatably installed on the supporting seat, a gear motor is fixedly installed on the supporting seat, and an output shaft of the gear motor is connected with the center of the gear.

Further, the gear motor is a forward and reverse rotating motor.

Furthermore, a feed inlet is formed in the top of the first shell, a screening motor is mounted on the side wall of the first shell, and an output shaft of the screening motor is connected with the first sieve plate.

Furthermore, a material guide motor is installed on the outer wall of the second shell, and an output shaft of the material guide motor is connected with the material guide plate.

Further, the material guiding motor is a forward and reverse rotating motor.

The utility model has the advantages that: the utility model provides a polyester chip sieving mechanism for producing polyester industrial yarn, polyester chip that the size is too little falls through the second sieve mesh preferentially, will accord with the size requirement and the polyester chip that the size is too big is detained and is stayed on the second sieve; then withdraw the second sieve, make the polyester chip that accords with size requirement fall through first sieve mesh preferentially, oversize polyester chip is detained on first sieve, so, filter the screening through the successive layer, sieve out oversize or undersize polyester chip in the raw materials, promoted the finished product performance of the polyester industrial yarn that follow-up production came out, and easy operation, convenient to popularize and use.

Drawings

The present invention will be further explained with reference to the drawings and examples.

FIG. 1 is a schematic structural diagram of a polyester chip screening device for producing polyester industrial yarns according to the present invention;

FIG. 2 is a cross-sectional view taken along A-A of the polyester chip screening apparatus for producing industrial polyester yarn shown in FIG. 1.

In the figure: 10. the shell, 11, first casing, 111, dog-house, 112, spout, 113, sieve material motor, 12, second casing, 121, supporting seat, 122, guide motor, 20, vibrating motor, 30, drive assembly, 31, gear, 32, rack, 33, second sieve, 331, second sieve mesh, 40, first sieve, 41, first sieve mesh, 50, stock guide, 60, first material receiving storehouse, 70, second material receiving storehouse.

Detailed Description

The present invention will now be described in detail with reference to the accompanying drawings. This figure is a simplified schematic diagram, and merely illustrates the basic structure of the present invention in a schematic manner, and therefore it shows only the constitution related to the present invention.

Referring to fig. 1, the present invention provides a polyester chip screening device for producing polyester industrial yarns, which is used for screening polyester chips, and includes a housing 10, a vibration motor 20 and a driving assembly 30 which are installed outside the housing 10, and a first sieve plate 40, a material guide plate 50, a first material receiving bin 60 and a second material receiving bin 70 which are installed inside the housing 10, wherein the first sieve plate 40 and the material guide plate 50 are both rotatably connected to the housing 10, the first sieve plate 40 is located above the material guide plate 50, the first sieve plate 40 is provided with a first sieve hole 41, the first material receiving bin 60 and the second material receiving bin 70 are oppositely disposed and located at two sides below the material guide plate 50, the driving assembly 30 includes a gear 31 rotatably disposed on the housing 10, a rack 32 engaged with the gear 31, and a second sieve plate 33 fixedly connected to the rack 32, the second sieve plate 33 can slidably penetrate through the side wall of the shell 10, a second sieve hole 331 is formed in the second sieve plate 33, the second sieve hole 331 corresponds to the first sieve hole 41 one by one, the aperture of the second sieve hole 331 is smaller than that of the first sieve hole 41, the second sieve plate 33 is located above the first sieve plate 40 and can be attached to the first sieve plate 40, and the second sieve hole 331 and the corresponding first sieve hole 41 are coaxially arranged.

The utility model discloses a polyester section sieving mechanism for producing polyester industrial yarn, during the use, rotate baffle 50 to the inclined position earlier, make the lower end of baffle 50 be located second receiving bin 70 one side, then drive second sieve 33 under the cooperation of gear 31, rack 32 insert in shell 10 and laminate with first sieve 40 in the outside of shell 10, second sieve 33 removes the back that targets in place, second sieve mesh 331 is coaxial with the first sieve mesh 41 that corresponds. Then, the vibrating motor 20 is started, and the polyester chips are poured onto the second sieve plate 33, and under the vibrating action, the polyester chips with the smaller size sequentially pass through the second sieve holes 331 and the first sieve holes 41, then fall onto the material guiding plate 50, and further fall into the second material receiving bin 70 under the guiding action of the material guiding plate 50. When no polyester chips fall, the material guide plate 50 is rotated reversely, so that the lower end of the material guide plate 50 is located at one side of the first material receiving bin 60, and then the second sieve plate 33 is driven to move outwards and separate from the first sieve plate 40 under the cooperation of the gear 31 and the rack 32, at this time, the polyester chips with the size meeting the requirement fall onto the material guide plate 50 after passing through the first sieve holes 41, and then fall into the first material receiving bin 60 under the guiding action of the material guide plate 50. When no polyester chip falls, the lower end of the material guide plate 50 is rotated to one side of the second material receiving bin 70 again, then the first sieve plate 40 is rotated to enable the first sieve plate 40 to be in an inclined state, at the moment, the polyester chip with the overlarge size rolls down onto the material guide plate 50 along the first sieve plate 40, then rolls down into the second material receiving bin 70 under the guiding effect of the material guide plate 50, so far, a screening process is completed, the processes are repeated after resetting of all parts, and therefore the continuous screening function can be realized.

In the above process, the polyester chips with small size preferentially fall through the second sieve 331, and the polyester chips with large size and meeting the size requirement are retained on the second sieve 33; and then withdrawing the second sieve plate 33, so that the polyester chips meeting the size requirement preferentially fall through the first sieve hole 41, and the polyester chips with overlarge size are retained on the first sieve plate 40, so that the overlarge or undersize polyester chips in the raw materials are screened out through filtering and screening layer by layer, and the finished product performance of the subsequently produced polyester industrial yarns is improved.

Specifically, the housing 10 includes a first housing 11 and a second housing 12, both of which have hollow structures inside, and the second housing 12 is connected to the lower end of the first housing 11, wherein the first screen plate 40 is rotatably installed in the first housing 11, the vibration motor 20 is installed on the outer wall of the first housing 11, and when the first screen plate 40 rotates to a horizontal state, the side wall of the first screen plate 40 is attached to the inner wall of the first housing 11, so as to prevent the polyester chips from falling. In addition, a feeding port 111 is formed at the top of the first casing 11, and the feeding port 111 is used for a user to feed the polyester chip into the casing 10. Referring to fig. 2, in a specific embodiment, a material sieving motor 113 is installed on a side wall of the first casing 11, an output shaft of the material sieving motor 113 is connected to the first sieve plate 40, and the material sieving motor 113 drives the first sieve plate 40 to rotate when being started.

Referring to fig. 1 again, the side wall of the first casing 11 is provided with a sliding slot 112, the sliding slot 112 penetrates through the inner and outer side walls of the first casing 11, and the second screen plate 33 is connected with the sliding slot 112 in a sliding fit manner. The chute 112 guides the sliding of the second screen deck 33 and prevents the gear 31 and the rack 32 from being disengaged. In a specific embodiment, a supporting seat 121 is installed on an outer wall of the second housing 12, the gear 31 is rotatably installed on the supporting seat 12, a gear motor (not shown) is fixedly installed on the supporting seat 121, an output shaft of the gear motor is connected with a center of the gear 31, and in use, the gear 31 can be driven by the gear motor to rotate forward and backward. In addition, the gear motor is a forward and reverse rotating motor.

The guide plate 50 is rotatably installed in the second housing 12, and the first receiving chamber 60 and the second receiving chamber 70 are disposed in the second housing 12. Referring to fig. 2 again, a material guiding motor 122 is installed on the outer wall of the second casing 12, and an output shaft of the material guiding motor 122 is connected to the material guiding plate 50, so that the material guiding motor 122 can drive the material guiding plate 50 to rotate when being started. In addition, the material guiding motor 122 is a forward and reverse rotation motor to make the material guiding plate 50 rotate clockwise and counterclockwise in a reciprocating manner.

The utility model provides a polyester section sieving mechanism for producing polyester industrial yarn through the cooperation between first sieve 40 and the second sieve 33, has realized successive layer screening function, can effectively screen out too big or the polyester section of undersize in the raw materials, has promoted the finished product performance of the polyester industrial yarn that follow-up production came out to, easy operation, convenient to popularize and use.

In light of the foregoing, it will be apparent to those skilled in the art from this disclosure that various changes and modifications can be made without departing from the scope of the invention. The technical scope of the present invention is not limited to the content of the specification, and must be determined according to the scope of the claims.

Claims (8)

1. The utility model provides a polyester chip sieving mechanism for producing dacron industrial yarn which characterized in that: the screen plate comprises a shell, a vibrating motor and a driving component which are arranged outside the shell, and a first screen plate, a guide plate, a first receiving bin and a second receiving bin which are arranged inside the shell, wherein the first screen plate and the guide plate are both rotatably connected with the shell, the first screen plate is positioned above the guide plate, a first sieve mesh is arranged on the first screen plate, the first receiving bin and the second receiving bin are oppositely arranged and positioned at two sides below the guide plate, the driving component comprises a gear which is rotatably arranged on the shell, a rack which is meshed with the gear and a second screen plate which is connected on the rack, the second screen plate can slidably penetrate through the side wall of the shell, a second sieve mesh is arranged on the second screen plate, the second sieve mesh corresponds to the first sieve mesh one by one, and the aperture of the second sieve mesh is smaller than that of the first sieve mesh, the second sieve is located the top of first sieve and can with first sieve is laminated mutually, and makes the second sieve mesh with correspond first sieve mesh coaxial arrangement.

2. The polyester chip screening device for producing the industrial polyester yarn as claimed in claim 1, wherein: the shell is including inside first casing and the second casing that is hollow structure, the second casing is connected the lower extreme of first casing, first sieve is rotationally installed in the first casing, vibrating motor installs on the outer wall of first casing, the stock guide is rotationally installed in the second casing, first receipts feed bin with second receipts feed bin all sets up in the second casing.

3. The polyester chip screening device for producing the industrial polyester yarn as claimed in claim 2, wherein: the side wall of the first shell is provided with a sliding groove, the sliding groove penetrates through the inner side wall and the outer side wall of the first shell, and the second sieve plate is connected with the sliding groove in a sliding fit mode.

4. The polyester chip screening device for producing the industrial polyester yarn as claimed in claim 3, wherein: the outer wall of the second shell is provided with a supporting seat, the gear is rotatably arranged on the supporting seat, the supporting seat is fixedly provided with a gear motor, and an output shaft of the gear motor is connected with the center of the gear.

5. The polyester chip screening device for producing the industrial polyester yarn as claimed in claim 4, wherein: the gear motor is a positive and negative rotation motor.

6. The polyester chip screening device for producing the industrial polyester yarn as claimed in claim 2, wherein: a feed inlet is formed in the top of the first shell, a screening motor is mounted on the side wall of the first shell, and an output shaft of the screening motor is connected with the first sieve plate.

7. The polyester chip screening device for producing the industrial polyester yarn as claimed in claim 2, wherein: and a material guide motor is installed on the outer wall of the second shell, and an output shaft of the material guide motor is connected with the material guide plate.

8. The polyester chip screening device for producing the industrial polyester yarn as claimed in claim 7, wherein: the material guiding motor is a forward and reverse rotating motor.

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