CN116175820A - Processing equipment for regenerating fine denier high-strength terylene industrial yarn - Google Patents

Abstract

The invention discloses a processing device for regenerating fine denier high-strength terylene industrial yarn, which comprises: a tank body configured to have a cleaning space for cleaning the polyester bottle; the conveying belt is used for conveying the polyester bottles into the tank body; the storage box is used for the polyester bottle to be cleaned; the material loading block is arranged on the conveying belt; the positioning block is arranged in the tank body; the cleaning rod is arranged at one side of the positioning block; the material loading block is provided with a first material loading groove, the positioning block is provided with a second material loading groove, and the second material loading groove is internally provided with a scraping block; when the material loading block is arranged on the positioning block, the cleaning rod stretches into the first material loading groove, and the cleaning rod at least has a first state of rotating relative to the polyester bottle and a second state of driving the polyester bottle to rotate together; the invention has simple structure and convenient use.

Description

Processing equipment for regenerating fine denier high-strength terylene industrial yarn

Technical Field

The invention belongs to the technical field of polyester industrial yarn processing, and particularly relates to processing equipment for regenerated fine denier high-strength polyester industrial yarn.

Background

The polyester industrial yarn is produced by adopting a solid-phase polycondensation melt spinning process route at home and abroad generally, namely, the low-viscosity polyester melt obtained by melt polycondensation is subjected to granulating, drying, crystallizing and solid-phase polycondensation to obtain high-viscosity polyester slices with the intrinsic viscosity of 0.90-1.10 d l/g, and the slices are subjected to melt spinning by adopting a screw extruder after being dried.

The processing technology of the regenerated fine denier polyester industrial yarn disclosed in the patent number CN113320046A comprises the following steps: s1, preparing regenerated polyester bottle flakes; s2, solid phase tackifying; s3, multi-head spinning; s4, drafting and heat setting; s5, winding and forming; when the polyester bottle is collected and cleaned, the label on the surface of the polyester bottle needs to be removed and the polyester bottle needs to be cleaned, and the automatic equipment structure of the operation is too complex at present and is not suitable for common factories.

Disclosure of Invention

The content of the present application is intended to introduce concepts in a simplified form that are further described below in the detailed description. The section of this application is not intended to identify key features or essential features of the claimed subject matter, nor is it intended to be used to limit the scope of the claimed subject matter.

The invention provides processing equipment for regenerating fine denier high-strength terylene industrial yarns, which aims to overcome the defects of the prior art.

In order to achieve the above purpose, the present invention adopts the following technical scheme: a processing equipment for regenerating fine denier high-strength terylene industrial yarn comprises: a tank body configured to have a cleaning space for cleaning the polyester bottle; the conveying belt is used for conveying the polyester bottles into the tank body; the storage box is used for the polyester bottle to be cleaned; the material loading block is arranged on the conveying belt; the positioning block is arranged in the tank body; the cleaning rod is arranged at one side of the positioning block; the material loading block is provided with a first material loading groove, the positioning block is provided with a second material loading groove, and the second material loading groove is internally provided with a scraping block; when the material loading block is arranged on the positioning block, the cleaning rod stretches into the first material loading groove, and the cleaning rod at least has a first state of rotating relative to the polyester bottle and a second state of driving the polyester bottle to rotate together.

Further, the processing equipment for regenerating the fine denier high-strength terylene industrial yarn further comprises: the first connecting rod is arranged on the tank body; the friction plate is arranged on the first connecting rod; when the material loading block drives the polyester bottle to move on the conveying belt, the bottle cap of the polyester bottle is contacted with the friction plate, so that the bottle cap of the polyester bottle is separated from the bottle body of the polyester bottle.

Further, the processing equipment for regenerating the fine denier high-strength terylene industrial yarn further comprises: the first connecting block is arranged on the loading block; the fixing plate is used for fixing the first connecting block on the conveying belt; the conveyor belt is provided with a connecting groove corresponding to the first connecting block, and the side wall of the connecting groove is provided with a first movable groove for accommodating the fixed plate.

Further, the processing equipment for regenerating the fine denier high-strength terylene industrial yarn further comprises: the guide block is arranged on the positioning block; the first push rod is arranged on the fixed plate; the stop lever is arranged in the pool body; when the material loading block moves to the upper part of the positioning block, the stop lever pushes the first push rod to move so that the fixed plate enters the first movable groove.

Further, be equipped with the first logical groove that supplies first push rod to remove on the fixed plate for the processing equipment of regeneration fine denier high strength polyester industrial yarn still includes: the first pushing block pushes the first pushing rod to move downwards; the support block is rotatably connected to one end of the fixed plate; the supporting block can only be turned upwards, and a first chute is arranged on the first pushing block.

Further, the processing equipment for regenerating the fine denier high-strength terylene industrial yarn further comprises: the first cylinder is arranged on the positioning block; the first push plate is arranged on a piston rod of the first cylinder; the loading block is provided with a second movable groove for accommodating the first connecting block.

Further, the processing equipment for regenerating the fine denier high-strength terylene industrial yarn further comprises: the second connecting block is arranged in the tank body; the second cylinder is arranged on the second connecting block; the motor is arranged on a piston rod of the second cylinder and drives the cleaning rod to rotate; the material loading block is provided with a plurality of second through grooves, and the positioning block is provided with a plurality of third through grooves.

Further, the processing equipment for regenerating the fine denier high-strength terylene industrial yarn further comprises: the third connecting block is arranged on the cleaning rod; the cleaning plate is arranged on the third connecting block; a plurality of bristles arranged on the cleaning plate; the second push rod pushes the third connecting block to move away from the cleaning rod; the cleaning rod is provided with a through cavity for the second push rod to pass through.

Further, the processing equipment for regenerating the fine denier high-strength terylene industrial yarn further comprises: the mounting rod is arranged on the third connecting block; the movable ring is arranged on the cleaning rod; the second connecting rod is used for connecting the movable ring and the third connecting block; the second push rod penetrates through the movable ring, and a third movable groove for the cleaning plate to move is formed in the mounting rod.

Further, the processing equipment for regenerating the fine denier high-strength terylene industrial yarn further comprises: the second push plate is arranged on the positioning block; the third push rod is arranged at one side of the second push rod; the third connecting rod is arranged on the third push rod; the second pushing block is arranged on the third connecting rod; the first lug is arranged at the bottom of the scraping block; the second push plate is arranged at one end of the second carrying groove.

The invention has the advantages that: the processing equipment for the regenerated fine denier high-strength polyester industrial yarn is simple in structure and convenient to use.

Drawings

The accompanying drawings, which are incorporated in and constitute a part of this application, are included to provide a further understanding of the application and to provide a further understanding of the application with regard to the other features, objects and advantages of the application. The drawings of the illustrative embodiments of the present application and their descriptions are for the purpose of illustrating the present application and are not to be construed as unduly limiting the present application.

In addition, the same or similar reference numerals denote the same or similar elements throughout the drawings. It should be understood that the figures are schematic and that elements and components are not necessarily drawn to scale.

In the drawings:

fig. 1 is a schematic structural view of a processing apparatus for regenerating fine denier high-strength polyester industrial yarn according to an embodiment of the present invention.

Fig. 2 is a cross-sectional view of a carrier block of the processing apparatus for regenerating fine denier high-strength polyester industrial yarn in the embodiment shown in fig. 1.

Fig. 3 is an enlarged view of a third pusher of the processing apparatus for regenerating fine denier high strength polyester industrial yarn in the embodiment shown in fig. 1.

Fig. 4 is a cross-sectional view of the embodiment of fig. 1 at a positioning block of a processing apparatus for regenerating fine denier high-strength polyester industrial yarn.

Fig. 5 is an enlarged view of a scraper of the processing apparatus for regenerating fine denier high-strength polyester industrial yarn in the embodiment shown in fig. 1.

Fig. 6 is a sectional view of the embodiment of fig. 1 at a first movable tank of a processing apparatus for regenerating fine denier high-strength polyester industrial yarn.

Fig. 7 is an enlarged view of a first push rod of the processing apparatus for regenerating fine denier high-strength polyester industrial yarn in the embodiment shown in fig. 1.

Fig. 8 is a sectional view of a second connection block of the processing apparatus for regenerating fine denier high-strength polyester industrial yarn in the embodiment shown in fig. 1.

Fig. 9 is an enlarged view of a cleaning plate of the processing apparatus for regenerating fine denier high-strength polyester industrial yarn in the embodiment shown in fig. 1.

Fig. 10 is an enlarged view of a second push plate of the processing apparatus for regenerating fine denier high-strength polyester industrial yarn in the embodiment shown in fig. 1.

Fig. 11 is a cross-sectional view of the embodiment of fig. 1 at a second groove of the processing apparatus for regenerating fine denier high-strength polyester industrial yarn.

Fig. 12 is an enlarged view of a movable block of a processing apparatus for regenerating fine denier high-strength polyester industrial yarn in the embodiment shown in fig. 1.

Fig. 13 is a sectional view of a cleaning bar of a processing apparatus for regenerating fine denier high-strength polyester industrial yarn in the embodiment shown in fig. 1.

Fig. 14 is an enlarged view of a baffle plate of the processing apparatus for regenerating fine denier high-strength polyester industrial yarn in the embodiment shown in fig. 1.

The meaning of the reference numerals in the figures is as follows:

101. a cell body; 102. a driving wheel; 103. a conveyor belt; 104. a storage bin; 105. a first connecting rod; 1051. a friction plate; 106. a loading block; 107. a positioning block; 1071. a guide block; 108. a cleaning rod; 109. a discharge plate; 110. a fixing plate; 1101. a second connecting spring; 1102. a support block; 1103. a first slider; 1104. a first return spring; 111. a first connection block; 1111. a second return spring; 112. a fixed block; 1121. a first connecting spring; 113. a limiting block; 114. a third push block; 1141. a support spring; 1142. a fourth connecting rod; 115. a first cylinder; 1151. a first push plate; 116. scraping blocks; 1161. a fourth connecting spring; 1162. a second bump; 117. a first push rod; 118. a first push block; 118a, a first chute; 119. a stop lever; 120. a second connection block; 121. a second cylinder; 122. a motor; 124. a connecting ring; 1241. a guide rod; 125. a second push rod; 126. a third connecting block; 1261. a mounting rod; 127. cleaning the plate; 1271. a sixth connecting spring; 128. a movable ring; 1281. a third return spring; 129. a second connecting rod; 130. umbrella cover cloth; 131. a second push plate; 1311. a third connecting spring; 132. a third push rod; 1321. a fourth return spring; 1322. a third connecting rod; 1323. a second push block; 133. a third push plate; 1331. a fifth connecting spring; 134. a fourth push block; 1341. a fifth return spring; 135. a movable block; 136. a stop block; 137. a fifth push block; 1371. a second slider; 138. a sixth return spring; 139. a third groove; 140. and a baffle.

Detailed Description

Embodiments of the present disclosure will be described in more detail below with reference to the accompanying drawings. While certain embodiments of the present disclosure are shown in the drawings, it should be understood that the present disclosure may be embodied in various forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete. It should be understood that the drawings and embodiments of the present disclosure are for illustration purposes only and are not intended to limit the scope of the present disclosure.

It should be noted that, for convenience of description, only the portions related to the present invention are shown in the drawings. Embodiments of the present disclosure and features of embodiments may be combined with each other without conflict.

It should be noted that the terms "first," "second," and the like in this disclosure are merely used to distinguish between different devices, modules, or units and are not used to define an order or interdependence of functions performed by the devices, modules, or units.

It should be noted that references to "one", "a plurality" and "a plurality" in this disclosure are intended to be illustrative rather than limiting, and those of ordinary skill in the art will appreciate that "one or more" is intended to be understood as "one or more" unless the context clearly indicates otherwise.

The names of messages or information interacted between the various devices in the embodiments of the present disclosure are for illustrative purposes only and are not intended to limit the scope of such messages or information.

The present disclosure will be described in detail below with reference to the accompanying drawings in conjunction with embodiments.

1-14, the processing equipment for regenerating the fine denier high-strength terylene industrial yarn comprises a pool body 101, a conveying belt 103, a driving wheel 102, a storage box 104, a loading block 106, a positioning block 107 and a cleaning rod 108.

The cell body 101 is constructed to have a washing space for washing the polyester bottle; the conveyor belt 103 conveys the polyester bottles into the tank body 101; the two driving wheels 102 are arranged above the pool body 101, and the two driving wheels 102 are wound on the two driving wheels 102 by the conveying belt 103; the storage box 104 is used for polyester bottles to be cleaned, and the storage box 104 is arranged above the conveying belt 103; the carrier block 106 is arranged on the conveyer belt 103; the positioning block 107 is arranged in the tank body 101; the cleaning rod 108 is arranged on one side of the positioning block 107; the material loading block 106 is provided with a first material loading groove, the positioning block 107 is provided with a second material loading groove, and the second material loading groove is internally provided with a scraping block 116; when the carrier block 106 is placed on the positioning block 107, the cleaning rod 108 extends into the first carrier groove, and the cleaning rod 108 at least has a first state of rotating relative to the polyester bottle and a second state of driving the polyester bottle to rotate together.

When the conveyer belt 103 drives the material loading block 106 to move to the bottom of the material storage box 104, the polyester bottles in the material storage box 104 drop on the material loading block 106, the polyester bottles are fixed in the first material loading groove, so that the polyester bottles move along with the movement of the material loading block 106, after the conveyer belt 103 conveys the material loading block 106 filled with the polyester bottles into the tank body 101, the material loading block 106 moves to the positioning block 107, the material loading block 106 wraps the polyester bottles by utilizing the first material loading groove and the second material loading groove after dropping on the positioning block 107, the cleaning rod 108 is inserted into the polyester bottles, the cleaning rod 108 rotates relative to the polyester bottles firstly to clean the inner walls of the polyester bottles, then the cleaning rod 108 drives the polyester bottles to rotate together, the scraping block 116 abuts against the side walls of the polyester bottles, the labels on the side walls of the polyester bottles are scraped by the scraping block 116, the automatic cleaning and label removing purposes of the polyester bottles are achieved, and the polyester bottles are more convenient to process.

A fourth movable groove is formed in the inner wall of the first material loading groove, a fixed block 112 is arranged in the fourth movable groove, a first connecting spring 1121 is arranged on the side wall of the fixed block 112, and one end of the first connecting spring 1121 is fixedly connected to the inner wall of the fourth movable groove; a fifth movable groove is formed in the side wall of the fourth movable groove, a first limiting block 113 is arranged in the fifth movable groove, an eighth reset spring is arranged on the first limiting block 113, and a limiting groove corresponding to the first limiting block 113 is formed in the fixed block 112; a sixth movable groove is formed in the inner wall of the first loading groove, a third push block 114 is arranged in the sixth movable groove, a supporting spring 1141 is arranged on the third push block 114, and the third push block 114 is connected with the first limiting block 113 through a fourth connecting rod 1142.

After the polyester bottle falls in the first loading groove, the polyester bottle pushes the third push block 114 to move, the third push block 114 drives the first limiting block 113 to move, the first limiting block 113 is separated from the limiting groove, the first connecting spring 1121 pushes the fixing block 112 to extend out of the fourth movable groove, the fixing block 112 abuts against the side wall of the polyester bottle to fix the polyester bottle, and the polyester bottle is prevented from falling from the loading block 106 in the conveying process.

The cell body 101 is provided with a first connecting rod 105, the first connecting rod 105 is provided with a friction plate 1051, the friction plate 1051 is positioned above the conveyor belt, and the friction plate 1051 is provided with a second chute.

After the polyester bottle is positioned on the loading block 106, the conveyor belt 103 drives the loading block 106 to move, the bottle cap part of the polyester bottle stretches out of the first loading groove, the bottle cap contacts with the surface of the friction plate 1051 when moving along with the loading block 106, and the bottle cap rotates when moving along with the loading block 106, so that the bottle cap is automatically removed when moving; the second chute is arranged to enable the bottle cap to be more attached to the friction plate 1051, so that the bottle cap of the polyester bottle is separated from the polyester bottle before the polyester bottle enters the tank body 101.

The conveyor belt 103 is provided with a plurality of connecting grooves corresponding to the first connecting blocks 111, the inner wall of each connecting groove is provided with a first movable groove, a second connecting spring 1101 is arranged in each first movable groove, one end of each second connecting spring 1101 is provided with a fixed plate 110, and the first connecting block 111 is provided with a fourth groove corresponding to the fixed plate 110; one end of the fixed plate 110 is rotatably connected with a supporting block 1102, and the supporting block 1102 can only be turned upwards; the fixed plate 110 is provided with a first through groove, a first push rod 117 is arranged in the first through groove, a first sliding block 1103 is arranged in the first through groove, a first sliding groove corresponding to the first sliding block 1103 is arranged on the first push rod 117, and a first reset spring 1104 is arranged on the first sliding block 1103; the top of the first movable groove is provided with a first push block 118, and one end of the first push block 118 is provided with a first chute 118a; a stop lever 119 is arranged on the inner wall of the tank body 101, and the stop lever 119 is arranged above the positioning block 107.

When the first connecting block 111 is positioned in the connecting groove, the fixed plate 110 extends out of the first movable groove, the first push rod 117 is positioned at the bottom of the first push block 118, the first push block 118 pushes the first push rod 117 to extend out of the first through groove, after the carrying block 106 moves into the tank body 101, the first push rod 117 abuts against the stop lever 119, when the conveying belt 103 drives the carrying block 106 to move continuously, the stop lever 119 pushes the first push rod 117 to move, the first push rod 117 drives the fixed plate 110 to enter the first movable groove, the fixed plate 110 is separated from the fourth groove, the carrying block 106 falls out of the connecting groove after losing the supporting force, the carrying block 106 directly falls on the positioning block 107, and the carrying block 106 and the positioning block 107 are matched to fix the polyester bottle so as to clean the polyester bottle by using the cleaning rod 108; when the first push rod 117 moves along the first push block 118, the first push rod 117 moves to one side of the first push block 118, after the first push rod 117 loses the supporting force, the first reset spring 1104 pushes the first push rod 117 to move upwards, the first push rod 117 moves away from one side of the stop lever 119, the conveying belt 103 continues to rotate, and the influence of the stop lever 119 on the rotation of the conveying belt 103 is avoided.

The material loading block 106 is provided with a plurality of second through grooves, the positioning block 107 is provided with a plurality of third through grooves, the second through grooves are communicated with the first material loading groove, and the third through grooves are communicated with the second material loading groove; guide blocks 1071 are respectively arranged on two sides of the positioning block 107, the guide blocks 1071 are of triangular structures, and the positioning block 107 is made of magnets.

The label paper scraped from the polyester bottle and impurities cleaned from the polyester bottle flow out from the second through groove and the second through groove along with water flow, and the first carrying groove and the second carrying groove are cleaned; after the carrier block 106 falls off the conveyor belt 103, the carrier block 106 falls on the positioning block 107, and the guide block 1071 positions the carrier block 106 so that the first carrier groove and the second carrier groove are aligned for positioning the polyester bottle; the carrier block 106 is made of iron alloy, so that the polyester bottle on the carrier block 106 can be immersed below the liquid level, and the polyester bottle can be cleaned; the magnetic force of the positioning block 107 is utilized to generate suction force on the material loading block 106, so that the matching effect of the material loading block 106 and the positioning block 107 is improved, and the polyester bottle is cleaned.

The positioning block 107 is provided with a first air cylinder 115, a piston rod of the first air cylinder 115 is provided with a first push plate 1151, and the top of the positioning block 107 is provided with a first groove for accommodating the first push plate 1151; the positioning block 107 is provided with a second movable groove, the first connecting block 111 is arranged in the second movable groove, the bottom of the first connecting block 111 is provided with a second reset spring 1111, and the bottom end of the second reset spring 1111 is propped against the bottom of the second movable groove.

After the polyester bottle is cleaned, the first air cylinder 115 drives the first push plate 1151 to move upwards, the first push plate 1151 pushes the loading block 106 to move upwards, and when the connecting groove does not rotate above the loading block 106, the first connecting block 111 is pushed into the second movable groove; when the connecting groove moves to the upper part of the loading groove, the second reset spring 1111 pushes the first connecting block 111 to extend out of the second movable groove, the first connecting block 111 is inserted into the connecting groove to push the supporting block 1102 to turn upwards, and the first connecting block 111 can be directly inserted into the connecting groove by the arrangement of the supporting block 1102; after the first connecting block 111 is inserted into the connecting groove, the first connecting block 111 moves towards the first movable groove under the action of inertia, the supporting block 1102 turns back, the fixing plate 110 is inserted into the fourth groove, the first connecting block 111 is fixed on the conveying belt 103 by utilizing the cooperation of the fixing plate 110 and the first connecting block 111, and the cleaned polyester bottle is transported out of the tank body 101.

The inner wall of the tank body 101 is provided with a second connecting block 120, the second connecting block 120 is provided with a mounting cavity, a second cylinder 121 and a motor 122 are arranged in the mounting cavity, the motor 122 is arranged on a piston rod of the second cylinder 121, an output shaft of the motor 122 is provided with a second push rod 125, the cleaning rod 108 is provided with a through cavity, the second push rod 125 is arranged in the through cavity in a penetrating manner, a movable cavity is arranged in the through cavity, the side wall of the movable cavity is provided with a guide groove, a third connecting block 126 is arranged in the guide groove in a penetrating manner, the third connecting block 126 is provided with a mounting rod 1261, the mounting rod 1261 is provided with a third movable groove, a cleaning plate 127 is arranged in the third movable groove, a sixth connecting spring 1271 and a plurality of bristles are arranged on the cleaning plate 127, and one end of the sixth connecting spring 1271 is fixedly connected to the bottom of the third movable groove; a movable ring 128 is arranged in the movable cavity, a second push rod 125 penetrates through the movable ring 128, a second connecting rod 129 is hinged to the bottom of the third connecting block 126, and the other end of the second connecting rod 129 is hinged to the movable ring 128; the second push rod 125 is provided with a ring groove, the movable ring 128 is provided with a third return spring 1281, one end of the third return spring 1281 is propped against the inner wall of the ring groove, the inner wall of the movable cavity is provided with a baffle 140, and one end of the baffle 140 is inserted into the ring groove; the cleaning rod 108 is provided with a connecting ring 124, the cleaning rod 108 is rotatably connected to the connecting ring 124, the connecting ring 124 is provided with a guide rod 1241, the second connecting block 120 is provided with a guide groove corresponding to the guide rod 1241, and the guide rod 1241 cannot be separated from the guide groove.

After the material loading block 106 drives the polyester bottle to move to the positioning block 107, the second cylinder 121 pushes the second push rod 125 to move towards the direction of the positioning block 107, the second push rod 125 drives the cleaning rod 108 to enter the polyester bottle, bristles are contacted with the inner wall of the polyester bottle, the motor 122 drives the second push rod 125 to rotate, the second push rod 125 drives the cleaning rod 108 to rotate, the bristles clean the inner wall of the polyester bottle, and impurities on the inner wall of the polyester bottle are scraped; after the cleaning of the inner wall of the polyester bottle is finished, the second cylinder 121 drives the second push rod 125 to continue to move, the guide rod 1241 moves to the end point of the guide groove and cannot move, the second push rod 125 moves relative to the cleaning rod 108, the second push rod 125 pushes the movable ring 128 to move, the movable ring 128 pushes the second connecting rod 129 to rotate, the second connecting rod 129 pushes the third connecting block 126 out of the movable cavity, the mounting rod 1261 moves away from the cleaning rod 108, bristles abut against the inner wall of the polyester bottle, the cleaning plate 127 moves into the third movable groove, the side wall of the mounting rod 1261 abuts against the inner wall of the polyester bottle to increase the contact area between the cleaning rod 108 and the polyester bottle, so that the friction force between the cleaning rod 108 and the polyester bottle is increased, when the motor 122 drives the second push rod 125 to rotate, the cleaning rod 108 drives the polyester bottle to rotate together, the scraping block 116 abuts against the side wall of the polyester bottle, and when the polyester bottle and the scraping block 116 relatively rotate, the label on the side wall of the polyester bottle is scraped, and the polyester bottle is separated; the baffle 140 limits the maximum distance that the movable ring 128 can move, and reduces the damage of the mounting rod 1261 to the body of the polyester bottle on the premise that the cleaning rod 108 can drive the polyester bottle to rotate together.

The cleaning rod 108 is provided with an umbrella fabric 130, the umbrella fabric 130 is provided with a supporting rod, the side wall of the through cavity is provided with a fifth through groove, the supporting rod is arranged in the fifth through groove in a penetrating mode, one end of the supporting rod is hinged to the second push rod 125, and the connection mode of the umbrella fabric 130 and the supporting rod is the same as that of an umbrella and a framework in the prior art.

The second push rod 125 drives the support rod to rotate when moving relative to the cleaning rod 108, the support rod drives the umbrella cloth 130 to open, and the cross-sectional area of the umbrella cloth 130 is increased, so that water flowing outside the bottle body is generated in the polyester bottle by using the umbrella cloth 130 when the cleaning rod 108 is taken out of the polyester bottle, and impurities cleaned from the inner wall of the polyester bottle are discharged from the bottle body.

A third connecting spring 1311 is arranged at one end of the second loading groove, a second push plate 131 is arranged at one end of the third connecting spring 1311, a seventh movable groove and an eighth movable groove communicated with the seventh movable groove are arranged at the bottom of the second loading groove, a scraping block 116 is arranged in the seventh movable groove, a fourth connecting spring 1161 is arranged at the bottom of the scraping block 116, the bottom of the fourth connecting spring 1161 is fixedly connected to the bottom of the seventh movable groove, a third push rod 132 is arranged in the eighth movable groove, the third push rod 132 extends out of the eighth movable groove, a third connecting rod 1322 is arranged on the third push rod 132, a second push block 1323 is arranged on the third connecting rod 1322, a third chute is arranged on the second push block 1323, and a first bump is arranged at the bottom of the scraping block 116; the third push rod 132 is located at one side of the second push plate 131, and a fourth return spring 1321 is provided on the third push rod 132.

A third pushing plate 133 is arranged at one end of the first loading groove, a fifth connecting spring 1331 is arranged on the third pushing plate 133, and one end of the fifth connecting spring 1331 is fixedly connected to the inner wall of the first movable groove; a ninth movable groove is further formed in the inner wall of the first movable groove, a fourth push block 134 is arranged in the ninth movable groove, a fifth reset spring 1341 is arranged on the fourth push block 134, one end of the fifth reset spring 1341 is fixedly connected to the inner wall of the ninth movable groove, and the fourth push block 134 and the fixed block 112 are connected together through a first connecting rope; a fourth push plate is provided at one end of the second push rod 125.

When the second push rod 125 moves relative to the cleaning rod 108, the fourth push plate pushes the polyester bottle to move, and the polyester bottle pushes the second push plate 131 and the third push plate 133 to move; when the third push plate 133 moves, the fourth push block 134 is pushed to move, the first connecting rope pulls the fixed block 112 to move into the fourth movable groove, and the fixed block 112 is separated from the side wall of the polyester bottle, so that the polyester bottle can rotate in the first loading groove; when the second push plate 131 moves, the third push rod 132 is pushed to move, the third push rod 132 drives the second push block 1323 to move, the second push block 1323 abuts against the end face of the first convex block, the second push block 1323 cooperates with the first convex block to push the scraping block 116 to move upwards, the scraping block 116 abuts against the side wall of the polyester bottle, and when the motor 122 drives the cleaning rod 108 to rotate, the polyester bottle is driven to rotate together, and the polyester bottle rotates relative to the scraping block 116 to scrape label paper; when the cleaning rod 108 moves out of the polyester bottle, the third connecting spring 1311 and the fifth connecting spring 1331 respectively push the second pushing plate 131 and the third pushing plate 133 to reset, and the fixing block 112 is propped against the side wall of the polyester bottle again to fix the polyester bottle in the first loading groove so as to convey the cleaned polyester bottle out.

The carrier block 106 is provided with a second groove, a movable block 135 and a stop block 136 are arranged in the second groove, the movable block 135 is provided with a sixth return spring 138, and one end of the sixth return spring 138 is propped against the stop block 136; the movable block 135 is provided with a second connecting rope, one end of the second connecting rope is fixedly connected to the fourth pushing block 134, the movable block 135 is provided with a sixth through groove, a fifth pushing block 137 is arranged in the sixth through groove, the fifth pushing block 137 is provided with a second sliding block 1371, the inner wall of the sixth through groove is provided with a second sliding groove corresponding to the second sliding block 1371, and the second sliding block 1371 is provided with a seventh reset spring; a third groove 139 is formed in the inner wall of the second groove, a guide groove is formed in the side wall of the third groove 139, a second bump 1162 is formed in the inner wall of the tank body 101, and the second bump 1162 is arranged at a corner of the conveying belt 103 which rotates out of the tank body 101; a discharge hole is arranged on the side wall of the tank body 101, a discharge plate 109 is arranged in the discharge hole, and the discharge plate 109 is obliquely arranged.

After the polyester bottle is washed, the first cylinder 115 pushes the loading block 106 to move upwards, the loading block 106 drives the washed polyester bottle to move together, the first connecting block 111 is connected to the conveying belt 103 again, the conveying belt 103 drives the loading block 106 to move, when the loading block 106 moves to the position of the second bump 1162, the second bump 1162 enters into the second groove, the fifth pushing block 137 abuts against the second bump 1162, when the loading block 106 moves, the fifth pushing block 137 drives the movable block 135 to move in the second groove, the second connecting rope pulls the fourth pushing block 134 to move, the first connecting rope pulls the fixed block 112 to move, the fixed block 112 enters into the fourth movable groove, the polyester bottle losing the fixing force at the corner of the conveying belt 103 falls out of the first loading groove, the polyester bottle directly falls on the discharging plate 109, the discharging plate 109 is utilized to take the polyester bottle out of the tank body 101, and the washed polyester bottle is collected.

The first connecting block 111 is provided with a notch for the baffle 140 to pass through, so that the carrier block 106 is driven by the conveying belt 103 to normally move.

The foregoing description is only of the preferred embodiments of the present disclosure and description of the principles of the technology being employed. It will be appreciated by those skilled in the art that the scope of the invention in the embodiments of the present disclosure is not limited to the specific combination of the above technical features, but encompasses other technical features formed by any combination of the above technical features or their equivalents without departing from the spirit of the invention. Such as the above-described features, are mutually substituted with (but not limited to) the features having similar functions disclosed in the embodiments of the present disclosure.

Claims (10)

1. A processing equipment for regenerating fine denier high-strength terylene industrial yarn comprises:

a tank body configured to have a cleaning space for cleaning the polyester bottle;

the conveying belt is used for conveying the polyester bottles into the tank body;

the storage box is used for the polyester bottle to be cleaned;

the method is characterized in that:

the processing equipment for the regenerated fine denier high-strength polyester industrial yarn further comprises:

the material loading block is arranged on the conveying belt;

the positioning block is arranged in the tank body;

the cleaning rod is arranged at one side of the positioning block;

the material loading block is provided with a first material loading groove, the positioning block is provided with a second material loading groove, and a scraping block is arranged in the second material loading groove;

when the material loading block is arranged on the positioning block, the cleaning rod stretches into the first material loading groove, and the cleaning rod at least has a first state of rotating relative to the polyester bottle and a second state of driving the polyester bottle to rotate together.

2. The processing apparatus for regenerating fine denier high-strength polyester industrial yarn as claimed in claim 1, characterized in that: further comprises:

the first connecting rod is arranged on the tank body;

the friction plate is arranged on the first connecting rod;

when the material loading block drives the polyester bottle to move on the conveying belt, the bottle cap of the polyester bottle is contacted with the friction plate, so that the bottle cap of the polyester bottle is separated from the bottle body of the polyester bottle.

3. The processing apparatus for regenerating fine denier high-strength polyester industrial yarn as claimed in claim 1, characterized in that: further comprises:

the first connecting block is arranged on the loading block;

a fixing plate for fixing the first connecting block to the conveyor belt;

the conveyer belt is equipped with the spread groove corresponding with first linkage piece, be equipped with on the spread groove lateral wall and be used for holding the first movable groove of fixed plate.

4. The processing apparatus for regenerating a fine denier high-strength polyester industrial yarn as claimed in claim 3, characterized in that: further comprises:

the guide block is arranged on the positioning block;

the first push rod is arranged on the fixed plate;

the stop lever is arranged in the pool body;

when the material loading block moves to the position above the positioning block, the stop lever pushes the first push rod to move so that the fixed plate enters the first movable groove.

5. The processing apparatus for regenerating fine denier high-strength polyester industrial yarn as claimed in claim 4, characterized in that: the fixed plate is provided with a first through groove for the first push rod to move, and the processing equipment for regenerating the fine denier high-strength polyester industrial yarn further comprises:

the first push block pushes the first push rod to move downwards;

the support block is rotatably connected to one end of the fixed plate;

the supporting block can only turn upwards, and a first chute is arranged on the first pushing block.

6. The processing apparatus for regenerating a fine denier high-strength polyester industrial yarn as claimed in claim 3, characterized in that: further comprises:

the first cylinder is arranged on the positioning block;

the first push plate is arranged on a piston rod of the first cylinder;

the loading block is provided with a second movable groove for accommodating the first connecting block.

7. The processing apparatus for regenerating fine denier high-strength polyester industrial yarn as claimed in claim 1, characterized in that: further comprises:

the second connecting block is arranged in the tank body;

the second cylinder is arranged on the second connecting block;

the motor is arranged on a piston rod of the second cylinder and drives the cleaning rod to rotate;

the material loading block is provided with a plurality of second through grooves, and the positioning block is provided with a plurality of third through grooves.

8. The processing apparatus for regenerating fine denier high-strength polyester industrial yarn as claimed in claim 7, characterized in that: further comprises:

the third connecting block is arranged on the cleaning rod;

the cleaning plate is arranged on the third connecting block;

a plurality of bristles arranged on the cleaning plate;

the second push rod pushes the third connecting block to move away from the cleaning rod;

the cleaning rod is provided with a through cavity for the second push rod to pass through.

9. The processing apparatus for regenerating fine denier high-strength polyester industrial yarn as claimed in claim 8, characterized in that: further comprises:

the mounting rod is arranged on the third connecting block;

the movable ring is arranged on the cleaning rod;

the second connecting rod is used for connecting the movable ring and the third connecting block;

the second push rod penetrates through the movable ring, and a third movable groove for the cleaning plate to move is formed in the mounting rod.

10. The processing apparatus for regenerating fine denier high-strength polyester industrial yarn as claimed in claim 1, characterized in that: further comprises:

the second push plate is arranged on the positioning block;

the third push rod is arranged at one side of the second push rod;

the third connecting rod is arranged on the third push rod;

the second pushing block is arranged on the third connecting rod;

the first lug is arranged at the bottom of the scraping block;

the second push plate is arranged at one end of the second carrying groove.

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