WO2023165084A1

WO2023165084A1 - Linear-type injection, blowing, filling, and sealing integrated plastic bottle packaging device

Info

Publication number: WO2023165084A1
Application number: PCT/CN2022/110426
Authority: WO
Inventors: 刘祥华; 黄盛秋; 张旭; 张昌凡; 郑湘明; 陈一
Original assignee: 湖南千山制药机械股份有限公司
Priority date: 2022-03-01
Filing date: 2022-08-05
Publication date: 2023-09-07
Also published as: CN114603823A

Abstract

A linear-type injection, blowing, filling, and sealing integrated plastic bottle packaging device, which comprises an injection molding module (100), a bottle blowing module (200), a filling module (500), and a sealing module (600) which are sequentially arranged in a linear manner; the injection molding module (100) is used for performing injection molding to form a line of bottle preforms; the bottle blowing module (200) is used for blow-molding the line of bottle preforms into a line of plastic bottles; the filling module (500) is used for filling a material into the line of plastic bottles; and the sealing module (600) is used for sealing the line of filled plastic bottles; the device further comprises a transfer mechanism (300) for performing translation on a line of material output by the injection molding module (100) and outputting a line of products after the material has sequentially entered the bottle blowing module (200), the filling module (500), and the sealing module (600); the whole plastic bottle manufacturing process, a conveying process, and a driving means are all simple and singular in nature, the transfer mechanism (300) only needs to perform a reciprocating translation action, synchronous press cap sealing operations for a plurality of plastic bottles can further be implemented, and sealing efficiency is effectively improved.

Description

Plastic bottle packaging equipment with linear injection, blowing, filling and sealing

technical field

The invention relates to the technical field of plastic bottle molding, in particular to a plastic bottle packaging equipment integrating linear injection, blowing, filling and sealing.

Background technique

Plastic bottle is a commonly used container, which is widely used in medical liquid containers, medical powder containers, medicine containers, beverage containers, seasoning containers, etc., so its demand is very large. The blowing process of plastic bottles is divided into one-step method and two-step method. The two-step blowing method is relatively widely used because of the high output of the machine, but the one-step blowing method has advantages in energy saving because it uses the residual temperature of the preform. If the output of one-step blow molding machine is increased to the level of two-step blow molding, then its advantages will be highlighted. The two representative companies of one-step blow molding machine are Japan's Aokigu and Nissei. Among them, Aokigu uses a three-station disc type, and the process is injection, blowing, and bottle output; Nissei uses a four-station disc type, and the process is injection, preheating, blowing, and bottle output . Although the process of the two is slightly different, they both adopt a disc structure. However, the disc structure severely limits the output of bottle blowing, which affects the output of plastic bottles accordingly. In addition, the filling and sealing process of plastic bottles is often separated from the production process of plastic bottles. Therefore, corresponding disinfection treatment is required before filling and sealing of plastic bottles, which is prone to problems such as incomplete disinfection and the introduction of impurities. In addition, after increasing the output of the same batch of plastic bottles, how to perform simultaneous and stable sealing operations on multiple plastic bottles has become a problem that needs to be solved.

Contents of the invention

The invention provides a linear plastic bottle packaging equipment integrating injection, blowing, filling and sealing to solve the above-mentioned problems in the prior art.

The invention provides a linear plastic bottle packaging equipment integrating injection, blowing, filling and sealing, which includes an injection molding module, a bottle blowing module, a filling module and a sealing module arranged in sequence in a straight line, and the injection molding modules are used for injection molding to form a row bottle blanks, the blowing module is used to blow mold the rows of bottle blanks into rows of plastic bottles, the filling module is used to fill the rows of plastic bottles with materials, and the sealing module is used to seal the filled bottles Rows of plastic bottles are sealed, and it also includes a transfer mechanism for translating the row of materials output by the injection molding module and sequentially entering the blowing module, the filling module and the sealing module to output the row of products ;

The sealing module includes a sealing frame, a sealing clamp bottle assembly arranged on the sealing frame and a sealing system arranged on the sealing frame, and the sealing clamp bottle assembly is used to clamp the entire row of plastics during sealing operation. bottle, the sealing system is used for synchronously sealing the entire row of plastic bottles, wherein the sealing system includes a first capping power mechanism, a second capping power mechanism, a capping slide rail, a capping connecting plate, a capping Take the cap rod and the capping frame, the fixed end of the first capping power mechanism is installed on the capping frame, the capping frame is installed on the sealing frame, the first The movable end of the capping power mechanism is connected to the fixed end of the second capping power mechanism, and the gland connecting plate is respectively connected to the movable end of the second capping power mechanism and the capping and capping lever. The capping slide rails are arranged on the capping frame, the capping connecting plate is slidably matched with the capping slide rails, and the first capping power mechanism and the second capping power mechanism are used to drive the The gland connecting plate slides up and down along the gland slide rail.

Further, a green body preheating module is arranged between the injection molding module and the bottle blowing module, and the injection molding module, the green body preheating module and the bottle blowing module are arranged sequentially in a straight line, and the The injection molding module translates the rows of blanks output by injection molding into the blank preheating module for preheating through the transfer mechanism, and then translates them into the blowing module for bottle blowing.

Further, the green body preheating module includes a preheating frame, a preheating auxiliary plate, a preheating linkage mechanism, a first movable template for preheating, a fixed template for preheating, a first preheating mold, a fixed preheating mold, The preheating slide rail and the preheating power mechanism, the preheating fixed template is fixed on the preheating frame, the preheating auxiliary plate and the first preheating movable template are slidably assembled on the preheating slide rail, The preheating first movable platen is between the preheating auxiliary plate and the preheating fixed platen, and the preheating linkage mechanism is between the preheating auxiliary plate and the preheating first movable platen , the power output end of the preheating power mechanism is connected to the preheating link mechanism, and the first preheating mold is fixed on the side of the preheating first movable template facing the preheating fixed template , the fixed preheating mold is fixed on the side of the preheating fixed template facing the first preheating mold, and the first preheating mold is relatively buckled with the fixed preheating mold to form a pair A row of preheating chambers for preheating the blanks at the same time.

Further, the green body preheating module includes a preheating frame, a preheating auxiliary plate, a preheating linkage mechanism, a preheating first movable template, a preheating second movable template, a preheating fixed template, a first preheating mold, the second preheating mold, fixed preheating mold, preheating Corinthian column and preheating power mechanism, the preheating fixed template is fixed on the preheating frame, and both sides of the preheating fixed template are provided with There is the fixed preheating mold, the preheating auxiliary plate, the first preheating movable platen, and the second preheating movable platen are slidably mounted on the preheating Corinthian column, and the preheating auxiliary plate The preheating link mechanism is provided between the preheating first movable template, the power output end of the preheating power mechanism is connected to the preheating link mechanism, and the preheating first movable template and the second preheating movable template are arranged on both sides of the preheating fixed template, the first preheating mold is fixed on the side of the first preheating movable template facing the preheating fixed template, and the The second preheating mold is fixed on the side of the preheating second movable template facing the preheating fixed template, and the first preheating mold is relatively buckled with the fixed preheating mold to form a row of blanks. A row of preheating cavities for simultaneous preheating, the second preheating mold and the fixed preheating mold are relatively engaged to form a row of preheating cavities for simultaneously preheating a row of blanks.

Further, the sealing clip bottle assembly includes a first sealing movable splint, a second sealing movable splint and a sealing bottle clamp driving device, and the first sealing movable splint is provided with a semicircular notch for forming a sealing station on the side facing the transfer mechanism , a plurality of semicircular notches are arranged at intervals along the length direction of the first sealing movable splint, a plurality of second sealing movable splints are movably arranged along the length direction of the first sealing movable splint and the second sealing movable splint is aligned with the semicircular notches One corresponding layout, the second sealing movable splint is provided with an arc notch on the side facing the corresponding semicircular notch, and the power output end of a sealing bottle clamp driving device is respectively connected to each second sealing movable splint and drives each second sealing movable splint The splints move synchronously, and the power output end of the other sealing bottle clamp driving device is connected to the first sealing movable splint and drives the first sealing movable splint and multiple second sealing movable splints to move synchronously, so that the semicircular notch and the arc notch Combined to form a hoop assembly for hooping the mouth of a plastic bottle.

Further, the transfer mechanism includes a transfer frame, a transfer bottle clamp and a slide mechanism, the slide mechanism is slidably connected to the transfer frame, the transfer bottle clamp is connected with the slide mechanism, and the transfer The bottle clamp is used to clamp the material, and the sliding mechanism is used to drive the transfer bottle clamp to move linearly in the width direction or the length direction to complete the material transfer.

Further, the sliding mechanism includes a first sliding mechanism and a second sliding mechanism, the second sliding mechanism is slidably connected to the transfer frame along the width direction, and the first sliding mechanism is slidable along the length direction Connected to the second sliding mechanism, the transfer bottle clamps are arranged in rows at intervals and assembled on the first sliding mechanism.

Further, the second sliding mechanism includes a transfer slide seat, a transfer second slide rail and a transfer second power device, the transfer second slide rail is arranged on the transfer frame along the width direction, and the transfer slide seat Installed on the transfer second slide rail and can slide back and forth along the transfer second slide rail, the power output end of the transfer second power device is connected with the transfer slide for driving the transfer slide Slide back and forth along the transfer second slide.

Further, the first sliding mechanism includes a transfer translation plate, a transfer first slide rail, a transfer connection plate and a transfer first power device, the transfer bottle clips are installed in a row on the transfer translation plate, and the transfer first A slide rail is arranged on the second sliding mechanism along the length direction, the transfer translation plate is installed on the transfer first slide rail and can slide back and forth along the transfer first slide rail, and the transfer connecting plate and The transfer translation plate is connected, and the power output end of the transfer first power device is connected to the transfer connection plate for driving the transfer connection plate and driving the transfer translation plate back and forth along the transfer first slide rail slide.

Further, it also includes a laminar flow hood for forming an aseptic airtight space and accommodating the injection molding module, the bottle blowing module, the filling module, the sealing module and the transfer mechanism.

The present invention has the following beneficial effects:

The linear injection, blowing, filling and sealing integrated plastic bottle packaging equipment of the present invention arranges the injection molding module, the blowing module, the filling module and the sealing module sequentially in the linear direction, and the injection molding module forms a row of materials and passes through the transfer mechanism. The rows of materials are moved horizontally and sequentially blown, filled and sealed, and then the rows of materials are output to complete the entire product preparation. The manufacturing process, conveying process, and driving mode of the entire plastic bottle are simple and single, and the transfer mechanism only needs to reciprocate The panning action does the trick. Moreover, due to the adoption of the linear injection, blowing, filling and sealing process, there is less interference and restrictions between various process links, and the number of blanks in rows and the number of packaged products obtained in rows are not easily limited by space, and can be easily realized. There are multiple rows of packaging products, or even multiple rows of the same batch production, so the output can be doubled or even dozens of times increased, providing a favorable process for the mass and rapid production of various plastic bottle packaging products Base. In addition, the production process of plastic bottles and the filling and sealing process are integrated to form a continuous production operation, which eliminates the need for sterilization before filling and sealing plastic bottles, which improves production efficiency and reduces production costs. Moreover, during the sealing operation, the entire row of plastic bottles is clamped by the sealing clamping bottle assembly to ensure the stability of the plastic bottles, and the first capping power mechanism is used to drive the capping and capping lever to take the cap down, and then through the second The two-glanding power mechanism drives the cap-taking lever and the plastic bottle to continue downward to realize the pressing of the plastic cap and the mouth of the plastic bottle, thereby realizing the synchronous capping and sealing operation of multiple plastic bottles, which effectively improves the sealing efficiency.

In addition to the objects, features and advantages described above, the present invention has other objects, features and advantages. Hereinafter, the present invention will be described in further detail with reference to the drawings.

Description of drawings

The accompanying drawings constituting a part of this application are used to provide further understanding of the present invention, and the schematic embodiments and descriptions of the present invention are used to explain the present invention, and do not constitute an improper limitation of the present invention. In the attached picture:

Fig. 1 is a schematic structural view of a linear injection, blowing, filling and sealing integrated plastic bottle packaging equipment in a preferred embodiment of the present invention; Fig. 2 is a schematic structural view of the injection molding state of an injection molding module in a preferred embodiment of the present invention; Fig. 3 is a preferred embodiment of the present invention Fig. 4 is a schematic structural view of the output state of the injection module of the preferred embodiment of the present invention after the green body is formed; Fig. 5 is a schematic view of the combined structure of the Haval plate and the Haval mold of the preferred embodiment of the present invention; Fig. 6 is the K-K sectional view of Fig. 5; Fig. 7 is the structural representation of the bottle blowing module of preferred embodiment of the present invention; Fig. 8 is the structural representation of the transfer mechanism of preferred embodiment of the present invention; Fig. 9 is the transfer of preferred embodiment of the present invention Schematic cross-sectional structure of the mechanism; Figure 10 is a schematic structural view of a green body preheating module in a preferred embodiment of the present invention; Figure 11 is a schematic top view of a green body preheating module in a preferred embodiment of the present invention; Figure 12 is a preferred embodiment of the present invention The structural schematic diagram of the body preheating module of the pushing and snapping mode of the embodiment; FIG. 13 is a structural schematic diagram of the filling module of the preferred embodiment of the present invention; FIG. 14 is the structure of the filling and clamping bottle assembly of the preferred embodiment of the present invention Schematic diagram; Fig. 15 is another structural representation of the filling module of the preferred embodiment of the present invention; Fig. 16 is another structural representation of the filling module of the preferred embodiment of the present invention; Fig. 17 is the sealing module of the preferred embodiment of the present invention Schematic diagram of the structure; Figure 18 is a schematic structural diagram of the screw cap sealing mechanism of the preferred embodiment of the present invention; Figure 19 is a schematic structural diagram of the T-direction perspective of Figure 18; Figure 20 is a schematic structural diagram of the cap feeding module of the preferred embodiment of the present invention; 21 is a front view of the appearance of the linear injection-blow-fill-seal integrated plastic bottle packaging equipment in a preferred embodiment of the present invention; FIG. 22 is a L-L sectional view of FIG. 21 .

illustration:

100. Injection molding module; 101. Blank mold assembly; 102. Haval plate; 103. Haval mold; 104. Opening wedge; 105. Transition slide rail; 106. Transition mold; 107. Lifting power device; 108. Horizontal power Device; 109, injection molding core rod; 200, bottle blowing module; 201, bottle blowing frame; 202, bottle blowing auxiliary plate; 203, bottle blowing linkage mechanism; Template; 206, the first dynamic blow mold for bottle blowing; 207, the fixed blow mold for bottle blowing; 208, the slide rail for bottle blowing; 209, the power mechanism for bottle blowing; 210, blowing parts; 213, bottle blowing brother Linzhu; 300, transfer mechanism; 301, transfer frame; 302, transfer bottle clamp; 303, transfer translation plate; 304, transfer the first slide rail; 305, Transfer sliding seat; 306, transfer the second slide rail; 307, transfer connecting plate; 309, transfer the first power device; 308, transfer the second power device; 400, green body preheating module; 401, preheating frame; 402 , preheating auxiliary plate; 403, preheating link mechanism; 404, preheating the first movable template; 405, preheating fixed template; 406, first preheating mold; 407, fixed preheating mold; 408, preheating power Mechanism; 409, preheating the second movable template; 410, the second preheating mold; 411, preheating the Corinthian column; 412, preheating the movable template; 413, the dynamic preheating mold; 500, the filling module; 502, filling clamp bottle assembly; 5021, the first filling movable splint; 5022, the second filling movable splint; 5023, filling bottle clamp driving device; 503, filling system; 5031, filling storage Material box; 5032, filling conveying pipe; 5033, filling valve; 5034, screw conveyor; 5035, storage hopper; 5036, vibration feeding device; 5037, counting and unloading device; 600, sealing module; 601, sealing frame ; 602, sealing clip bottle assembly; 603, sealing system; 6031b, the first gland power mechanism; 6032b, the second gland power mechanism; 6033b, gland slide rail; 6034b, gland connecting plate; Cap rod; 6036b, capping frame; 700, laminar flow hood; 800, cap feeding module; 801, vibration sorting device; 802, cap feeding plate; 803, cap feeding power mechanism.

Detailed ways

The embodiments of the present invention will be described in detail below with reference to the accompanying drawings, but the present invention can be implemented in various ways defined and covered below.

As shown in Fig. 1, Fig. 21 and Fig. 22, the linear injection-blowing-filling-sealing integrated plastic bottle packaging equipment of this embodiment is suitable for filling solid materials, and includes injection molding modules 100, The blank preheating module 400, the bottle blowing module 200, the filling module 500 and the sealing module 600, the injection molding module 100 is used for injection molding to form rows of materials, and the blank preheating module 400 is used for synchronously preheating the rows of preforms, The bottle blowing module 200 is used to synchronously blow mold the preheated rows of preforms into rows of plastic bottles, the filling module 500 is used to synchronously fill the rows of plastic bottles with a preset amount of solid materials, and the sealing module 600 is used for synchronously sealing the rows of plastic bottles after filling. The plastic bottle packaging equipment with linear injection, blowing, filling and sealing also includes a device for moving the rows of materials output by the injection molding module 100 and entering the green body in turn for preheating. After the module 400, bottle blowing module 200, filling module 500 and sealing module 600, the transfer mechanism 300 that outputs rows of products and is used to form a sterile sealed space and accommodate the injection molding module 100, the body preheating module 400, and the bottle blowing module 200 , the filling module 500, the sealing module 600 and the laminar flow hood 700 of the transfer mechanism 300. Linear plastic bottle packaging equipment with integrated injection, blowing, filling and sealing. The injection module 100, green body preheating module 400, bottle blowing module 200, filling module 500 and sealing module 600 are arranged in sequence in the linear direction, and are passed through the transfer mechanism. The transfer translation function of 300 connects the injection molding module 100, the green body preheating module 400, the blowing module 200, the filling module 500 and the sealing module 600 to form an overall structure; The row of materials is translated into the body preheating module 400 by the transfer mechanism 300 for synchronous preheating of the row of materials, and then the transfer mechanism 300 translates the preheated row of materials to the bottle blowing module 200 for the row of materials Synchronous bottle blowing, then the transfer mechanism 300 translates the blown rows of materials to the filling module 500 for synchronous filling, and finally transfers the filled rows of materials to the sealing module 600 through the transfer mechanism 300 for row The synchronous sealing of materials, and then the output of materials in rows, and then complete the entire product preparation. The manufacturing process, conveying process, and driving method of the entire plastic bottle are simple and single, and the transfer mechanism 300 only needs to move back and forth in translation; in addition, due to the linear injection, blowing, filling and sealing process, the interference between various process links is small and limited. The number of blanks in rows and the number of packaged products in rows are not easily limited by space, and it is easy to realize multiple rows of packaged products in rows, or even realize the same batch production of multiple rows, so the output can be obtained. Doubling, or even dozens of times, provides a favorable technological basis for the mass and rapid production of various plastic bottle packaging products. Moreover, the manufacturing process of plastic bottle packaging products, injection, blowing, filling and sealing are all completed in the aseptic and closed laminar flow hood 700, and there is no contact with the outside world throughout the whole process, thereby ensuring the quality of the packaged products. It is especially suitable for the manufacture and use of plastic bottle packaging products with high quality requirements for filling materials such as food, medicine, and chemicals. It can be understood that when some plastic particles are made into preforms and can be blown directly without preheating the preforms, the preform preheating module 400 can be omitted. In addition, the laminar flow hood 700 can also be omitted when the filling material has low requirements on sterility.

It can be understood that, as shown in FIG. 1 , the injection molding machine realizes the diversion of the injection molding material through the injection pipe, and enters the material flow paths of multiple blank mold assemblies 101 respectively, and then realizes the green body molding cavity of the blank mold assembly 101 Internal body molding. Preferably, the number of blank mold assemblies 101 is two groups. Optionally, the injection pipe itself has the function of thermal insulation, and a heating pipe clamp can also be arranged outside the injection pipe if necessary. Optionally, the blank forming cavities in the blank mold assembly 101 are arranged in a single row, and each blank forming cavity is arranged at intervals, and the number of blank forming cavities in a single row is 3-20. Optionally, the blank forming cavities in the blank mold assembly 101 are arranged in multiple rows, and each blank forming cavity is arranged at intervals; preferably, the blank forming cavities in the blank mold assembly 101 are arranged in two rows . Optionally, the preheating station of the green body preheating module 400, the bottle blowing station of the bottle blowing module 200, the filling station of the filling module 500, the sealing station of the sealing module 600 and the transfer bottle of the transfer mechanism 300 The arrangement of the clips 302 completely matches the arrangement of the blank molding cavities of the blank mold assembly 101 , and then through the simple reciprocating and translational movement of the transfer mechanism 300 , batch and rapid production of plastic bottle packaging products can be completed. The green body forming cavities of the injection molding module 100 are arranged at equal intervals; specifically, the green body forming cavities of the blank mold assembly 101 are arranged at equal intervals. A plurality of Haval molds 103 are arranged at equal intervals, and the distance between the central axes of two adjacent Haval molds 103 is the same as the distance between the central axes of two adjacent green body molding cavities. The blowing cavities of the bottle blowing module 200 are arranged at equal intervals, and the distance between the central axes of two adjacent blowing cavities is the same as the distance between the central axes of two adjacent blank molding cavities. The preheating chambers of the green body preheating module 400 are arranged at equal intervals, and the distance between the central axes of two adjacent preheating chambers is the same as the distance between the central axes of two adjacent green body forming cavities. The filling stations of the filling module 500 are arranged at equal intervals, and the distance between the central axes of two adjacent filling stations is the same as the distance between the central axes of two adjacent blank forming cavities. The sealing stations of the sealing module 600 are arranged at equal intervals, and the distance between the central axes of two adjacent sealing stations is the same as the distance between the central axes of two adjacent blank forming cavities. The transfer bottle clamps 302 of the transfer mechanism 300 are arranged at equal intervals, and the distance between the central axes of two adjacent transfer bottle clamps 302 is the same as the distance between the central axes of two adjacent green body molding cavities. As shown in Figure 21, the outer layer of the plastic bottle packaging equipment is a laminar flow hood 700, that is, a sterile and sealed laminar flow hood; Realize sterility, and enter the aseptic sealed laminar flow hood, and then go through the preheating of the green body preheating module 400, the blowing of the bottle blowing module 200, the filling of the filling module 500 and the sealing of the sealing module 600, Then the product is exported, and the whole process is completed under the protection of 100-level laminar flow, so as to realize aseptic production. Optionally, the output end of the sealing module 600 outputs the sealed product to the outside through a conveyor belt, as shown in FIG. 22 .

As shown in Figure 1, in the present embodiment, the arrangement direction of the green body forming cavities of the injection molding module 100, the arrangement direction of the preheating cavities of the green body preheating module 400, and the arrangement direction of the blowing cavities of the bottle blowing module 200 direction, the arrangement direction of the filling stations of the filling module 500 and the arrangement direction of the sealing stations of the sealing module 600 are arranged in the same direction, and are arranged in the same direction as the injection molding module 100 and the green body preheating module 400 arranged in a straight line. , bottle blowing module 200, filling module 500 and sealing module 600 are arranged in the same direction. In order to facilitate the simple translational movement of the transfer mechanism 300, the finished material molded from the injection molding module 100 is then preheated by the body preheating module 400, blown by the bottle blowing module 200, and filled and sealed by the filling module 500. The process of sealing the module 600 and then outputting the finished product can simplify the entire structural design, and the entire operation is simple. The transfer mechanism 300 assists each station to work in an orderly manner. The coordination and cooperation during the action process is smooth, and there is no complicated action. It is not easy to interfere with each other.

It can be understood that, in this embodiment, the injection molding module 100 includes a hopper, a barrel, a screw, a heating device, a backflow prevention valve, a driving device and a blank mold assembly 101, and the blank mold assembly 101 includes a first half mold, a second half mold Two half-side molds and a mold-closing driving mechanism for driving the first half-side mold and the second half-side mold to close or open the mold, and a plurality of blanks arranged in rows are correspondingly arranged between the first half-side mold and the second half-side mold The molding cavity and the material flow path connected to the green body molding cavity respectively, and the blank mold assembly 101 is also provided with an injection pipe for connecting to the material flow path; the material in the hopper falls into the barrel and is driven by the driving device The screw spirally pushes the material, and the heating device heats the material in the screw spiral pushing process and outputs it to the injection pipe of the blank mold assembly 101 to injection mold a row of green bodies in the blank mold assembly 101. By opening the blank mold set 101 to output rows of blanks; the anti-reflux valve is provided at one end of the screw rod facing the blank mold assembly 101 . The injection molding raw materials are stored in the hopper, and the injection molding raw materials in the hopper fall into the barrel, and the screw is driven by the driving device to rotate and the injection molding raw materials are pushed forward. During the advancing process, the injection molding raw materials are heated by the heating device to be plasticized and transformed into Viscous liquid state, through the helical propulsion of the screw, the liquid material is compressed, sheared, and stirred, so that the density and viscosity of the liquid material are uniform, and then injected into the material flow path of the blank mold assembly 101 through the injection tube and Enter the body molding cavity to realize the injection molding of the body. The anti-reflux valve not only plays the role of auxiliary compression, but also makes it impossible for the liquid material to flow back, so as to ensure the smooth output of uniform liquid material. When the green body is demolded after injection molding, the driving and rotating device stops running, and the first half mold is separated from the second half mold by the mold opening driving mechanism, and the overall translation is carried out through the transfer mechanism 300 . Optionally, the stripped body can be dropped to a preset position on the material platform in advance, and then clamped by the transfer mechanism 300 and then transferred. Optionally, the blank mold assembly 101 can first open the clamping position of the upper blank by the mold opening drive mechanism, and after the blank is clamped and fixed by the transfer mechanism 300, the first half mold and the second mold half can be connected by the mold opening drive mechanism. The half-side molds are separated, and then the row of blanks is driven by the transfer mechanism 300 to translate to the blank preheating module 400 and/or the bottle blowing module 200 .

Specifically, as shown in Figures 2 to 6, in this embodiment, the injection molding module 100 includes a blank mold assembly 101, a Haval plate 102, a Haval mold 103, a mold opening wedge 104, a transition slide rail 105, a transition mold 106, lifting power unit 107, horizontal power unit 108 and injection molding mandrel 109; Transition mold 106 is slidably assembled on the transition slide rail 105, and the fixed end of horizontal power unit 108 is installed on the transition slide rail 105, and horizontal power unit 108 The power output end of the transition mold 106 is connected, and the transition slide rail 105 is installed on the power output end of the lifting power device 107; the blank mold assembly 101 has rows of green body molding cavities arranged at intervals, injection core rods 109 and Haval The mold 103 and the green body forming cavity of the blank mold assembly 101 are vertically arranged in one-to-one correspondence; the Haval mold 103 is installed on the Haval plate 102 and is clamped and fixed by the elastic member on the Haval plate 102, and the closing of the Haval plate 102 There is a tapered groove at the seam, and the mold opening wedge 104 is movably matched with the tapered groove to push away the Haval plate 102, thereby realizing the automatic drop of the green body; the injection core rod 109 and the Haval plate 102 are relatively 101 is movably arranged up and down. The Haval plate 102 clamps the Haval molds 103 arranged in rows and falls onto the blank mold assembly 101, and the Haval molds 103 and the green body forming cavities of the blank mold assembly 101 are arranged in one-to-one correspondence, and the Haval molds 103 are docked on the blank mold assembly In the green body molding cavity of part 101; the injection core rod 109 falls and cooperates with the Haval mold 103 by sealing insertion, and quantitatively injects materials into the green body molding cavity; after the injection is completed, the injection core rod 109 rises vertically, and then The Haval plate 102 carries the Haval mold 103 up and the billet formed by the Haval mold 103 is released from the blank forming cavity; through the coordinated work of the lifting power device 107 and the horizontal power device 108, the transition die 106 is driven to move to the blank mold assembly 101 and Stop between the Haval molds 103; the Haval plate 102 carries the Haval mold 103 and collides with the mold opening wedge 104 during the ascent process, and makes the mold opening wedge 104 inserted into the tapered groove of the Haval plate 102, so that the Haval plate 102 Forced to overcome the elastic force of the elastic part, the mold is opened and separated, and then the Haval mold 103 is opened and separated, and the formed green body falls into the cavity of the corresponding transition mold 106, and the clamping of the green body formed by the Haval mold 103 The part is exposed to the outside of the mold cavity, and the clamping part of the green body is clamped by the transfer mechanism 300, so as to realize the overall translational transfer action of the row of green bodies. Optionally, the injection core rod 109 is connected to the output end of the injection molding machine through the injection tube. Optionally, both the Haval board 102 and the Haval mold 103 are composed of half molds; a sliding shaft is used to pass through the two half molds of the Haval board 102, and pre-tension springs are arranged at both ends of the sliding shaft and locked by fixing nuts , so that the two halves of the Haval board 102 remain close together; by arranging tapered grooves at the joint positions of the two halves of the Haval board 102, and making the tapered grooves correspond to the upper and lower mold opening wedges 104, and then During the rising process of the Haval plate 102, the mold opening wedge 104 is inserted into the tapered groove, so that the two half-side molds of the Haval plate 102 carry the two half-side molds of the Haval mold 103 respectively to open, and the green body falls freely. Optionally, the inner cavity of the Haval mold 103 is conical, so that the green body automatically corrects its position during the falling process and falls to the central axis of the transitional mold 106 to ensure the accuracy of the falling position, thereby ensuring that the transfer mechanism 300 is accurate and stable. Clamping of rows of blanks and overall translation of rows of blanks. Optionally, tapered grooves are respectively provided at both ends of the Harvard plate 102 , and the tapered grooves are arranged in one-to-one correspondence with the upper mold opening wedges 104 .

It can be understood that in this embodiment, the bottle blowing module 200 includes a bottle blowing frame 201, a bottle blowing auxiliary plate 202, a bottle blowing linkage mechanism 203, a first moving platen 204 for bottle blowing, a fixed plate plate 205 for bottle blowing, The first moving blow mold 206, the bottle blowing fixed blow mold 207, the bottle blowing slide rail 208, the bottle blowing power mechanism 209 and the blowing part 210; 1. The first moving template 204 for bottle blowing is slidably assembled on the bottle blowing slide rail 208, the first movable template 204 for bottle blowing is between the auxiliary bottle blowing plate 202 and the fixed bottle blowing template 205, and the bottle blowing linkage mechanism 203 is in the auxiliary bottle blowing Between the plate 202 and the first moving platen 204 for bottle blowing, the power output end of the bottle blowing power mechanism 209 is connected to the bottle blowing linkage mechanism 203; The first moving blow mold 206 is fixed on the side of the first moving platen 204 for bottle blowing towards the fixed platen 205 for bottle blowing, and the fixed blow mold 207 is fixed on the side of the fixed platen 205 for bottle blowing towards the first movable platen 204 for bottle blowing Above, the first movable blow mold 206 for bottle blowing is engaged with the fixed blow mold 207 to form rows of blowing cavities for simultaneously blowing rows of blanks. The first moving blow mold 206 for bottle blowing and the fixed blow mold 207 for bottle blowing are in the mold opening state, and the transfer mechanism 300 translates the rows of blanks from the injection molding module 100 or the blank preheating module 400 to the first movable blow mold 206 for bottle blowing. The bottle blowing station between the bottle blowing fixed blow mold 207; the bottle blowing power mechanism 209 drives the bottle blowing linkage mechanism 203 to unfold, and pushes the first movable mold plate 204 for bottle blowing to drive the first movable blow mold 206 to blow the bottle The bottle blowing fixed blow mold 207 on the fixed template 205 is fastened together to fix the green body. At this time, the bottle blowing first movable blow mold 206 and the bottle blowing fixed blow mold 207 are enclosed to form a bottle molding cavity that matches the shape of the plastic bottle. The air blowing parts 210 are arranged in a one-to-one correspondence with the bottle body forming cavity. Blow air through the blowing port of the inner blank so that the blank is inflated and expanded around until it completely fits with the inner wall of the bottle forming cavity, and then the blowing process of the plastic bottle is completed; the blowing part 210 rises, and the blowing power The mechanism 209 drives the bottle blowing link mechanism 203 to fold and shrink, so that the first moving blow mold 206 and the fixed blow mold 207 are separated and separated, and the transfer mechanism 300 carries the formed rows of plastic bottles to the next process as a whole. panning. Optionally, the bottle blowing first dynamic blow mold 206 and the bottle blowing fixed blow mold 207 are enclosed to form a bottle molding cavity with a lower opening, and the bottle blowing module 200 also includes a bottoming part that can be lifted and lowered on the bottle blowing frame 201 The base part is used to form the bottom shape of the plastic bottle. Optionally, the bottle blowing slide 208 adopts Corinthian poles. Optionally, the bottle blowing auxiliary plate 202 can also be fixed on the bottle blowing frame 201, and the bottle blowing linkage mechanism 203 is driven by the bottle blowing power mechanism 209, thereby controlling the first moving blow mold 206 to approach or move away from the bottle blowing bottle. Determine the template 205. Optionally, the bottle blowing power mechanism 209 adopts a cylinder, an oil cylinder, a telescopic motor, a gear set drive mechanism, etc. or a similar driving mechanism; it can be driven in cooperation with the bottle blowing linkage mechanism 203; it can also be directly driven by the bottle blowing power mechanism 209.

Optionally, as shown in FIG. 7, in this embodiment, the bottle blowing module 200 includes a bottle blowing frame 201, a bottle blowing auxiliary plate 202, a bottle blowing linkage mechanism 203, a first moving platen 204 for bottle blowing, a bottle blowing The second movable mold plate 211 for bottle blowing, the fixed mold plate for bottle blowing 205, the first movable blow mold for bottle blowing 206, the second movable blow mold for bottle blowing 212, the fixed blow mold for bottle blowing 207, the bottle blowing column 213, and the bottle blowing power mechanism 209 And the blowing part 210; The bottle blowing fixed template 205 is fixed on the bottle blowing frame 201, and both sides of the bottle blowing fixed template 205 are provided with a bottle blowing fixed blow mold 207; Blowing auxiliary plate 202, bottle blowing first movable template 204 2. The second moving template 211 for bottle blowing is slidably assembled on the bottle blowing Gelin column 213. A bottle blowing linkage mechanism 203 is arranged between the bottle blowing auxiliary plate 202 and the first bottle blowing template 204. The power of the bottle blowing power mechanism 209 The output end is connected to the bottle blowing linkage mechanism 203; the first blowing platen 204 and the second blowing platen 211 are respectively arranged on both sides of the blowing fixed platen 205, and the first blowing platen 204 faces the blowing fixed platen 205 is fixed with the first blow mold 206 for bottle blowing, and the second movable mold plate 211 for bottle blowing is fixed with the second movable blow mold 212 for bottle blowing on the side facing the fixed mold plate 205 for bottle blowing; On the bottle frame 201; the first blowing mold 206 and the blowing fixed blowing mold 207 are relatively buckled together to form rows of blowing cavities for simultaneously blowing rows of blanks, and the second blowing mold 212 is buckled relatively with the bottle blowing fixed blow mold 207 to form rows of blowing cavities for simultaneously blowing rows of blanks. The bottle blowing first dynamic blow mold 206 and the bottle blowing fixed blow mold 207 and the bottle blowing second dynamic blow mold 212 and the bottle blowing fixed blow mold 207 are in the mold opening state, and the transfer mechanism 300 transfers the rows of blanks from the injection molding module 100 or the blanks The preheating module 400 is translated as a whole and enters the first blowing station between the first movable blow mold 206 and the fixed blow mold 207 and the second movable blow mold 212 and the fixed blow mold respectively. The second bottle blowing station between 207; the bottle blowing power mechanism 209 drives the bottle blowing linkage mechanism 203 to expand, and pushes the first movable mold plate 204 for bottle blowing to drive the first movable blow mold 206 to the fixed mold plate 205 for bottle blowing The bottle blowing fixed blow mold 207 buckles and fixes the green body, and the bottle blowing auxiliary plate 202 receives the force of the bottle blowing linkage mechanism 203 synchronously, and drives the bottle blowing second movable platen 211 to drive the bottle blowing second via the bottle blowing Gelin column 213 The second moving blow mold 212 buckles and fixes the green body toward the bottle blowing fixed blow mold 207 on the bottle blowing fixed mold plate 205. At this time, the first blowing blow mold 206 and the blowing fixed blow mold 207 are enclosed to form a shape corresponding to the shape of the plastic bottle. The matched first bottle body molding cavity, the first group of blowing parts 210 are arranged in a one-to-one correspondence with the first bottle body molding cavity, and the second dynamic blow mold 212 for bottle blowing is surrounded by the fixed blow mold 207 to form a The shape of the plastic bottle matches the second bottle body forming cavity, and the second group of blowing parts 210 are arranged in a one-to-one correspondence with the second bottle body forming cavity. Plug them into the blowing ports of the corresponding blanks respectively, and blow air into the blowing ports of the inner blanks through the blowing part 210, so that the blanks will inflate and expand around until they form a cavity with the first bottle body or the second bottle. The inner wall surface of the body molding cavity is completely attached, and then the blowing process of the plastic bottle is completed; the blowing part 210 rises, and the blowing power mechanism 209 drives the blowing linkage mechanism 203 to fold and shrink, so that the first blowing blowing part moves 206 is separated from the fixed blow mold 207 for bottle blowing, and the second dynamic blow mold 212 for bottle blowing is separated from the fixed blow mold 207 for bottle blowing. The transfer mechanism 300 carries the formed rows of plastic bottles to the next process as a whole. Optionally, the bottle blowing power mechanism 209 adopts a cylinder, an oil cylinder, a telescopic motor, a gear set driving mechanism, etc. or similar driving mechanism, which can be driven in cooperation with the bottle blowing linkage mechanism 203; it can also be directly driven by the bottle blowing power mechanism 209.

It can be understood that, as shown in FIG. 8 and FIG. 9 , the transfer mechanism 300 includes a transfer bottle clamp 302, a transfer frame 301 and a sliding mechanism, the sliding mechanism is slidably connected to the transfer frame 301, the The transfer bottle clamp 302 is connected with the sliding mechanism, the transfer bottle clamp 302 is used to clamp the material, and the sliding mechanism is used to drive the transfer bottle clamp 302 to move linearly in the width direction or the length direction to complete the material transfer. It can be understood that the length direction refers to the arrangement and extension direction of a plurality of processing stations, that is, when the transfer bottle clamp 302 moves in the length direction, the material can be transferred between a plurality of processing stations, and the The width direction refers to the extension direction between each station and the transfer mechanism 300, that is, when the transfer bottle clamp 302 moves in the width direction, materials can be sent into or out of the processing station. Wherein, the material refers to a preform or a plastic bottle, which is a preform before the bottle blowing station, and a plastic bottle at the bottle blowing station and subsequent processing stations.

It can be understood that the transfer mechanism 300 of the present embodiment is provided with a sliding mechanism that can slide along the length direction and the width direction on the transfer frame 301, and the transfer bottle clamp 302 is installed on the sliding mechanism, through the sliding The mechanism drives the transfer bottle clamp 302 to move linearly along the length direction or width direction, so as to realize the feeding or sending of materials at each processing station and the transfer of materials between multiple processing stations, which can realize the processing of materials in rows , the manufacturing process, conveying process, and driving mode of the entire plastic bottle are simple and single. The transfer mechanism 300 only needs to move back and forth in translation. There is less interference and restrictions between various processing links. The number of packaged products in a row is not easily limited by the space, and it is easy to realize the production of multiple or even multiple rows of the same batch of packaged products in a row, so the output can be doubled or even dozens of times improved. The mass and rapid production of various plastic bottle packaging products provides a favorable technological basis.

Wherein, the sliding mechanism specifically includes a first sliding mechanism and a second sliding mechanism, the second sliding mechanism is slidably connected to the transfer frame 301 along the width direction, and the first sliding mechanism is slidable along the length direction. Slidingly connected to the second sliding mechanism, the transfer bottle clamps 302 are arranged in rows at intervals and assembled on the first sliding mechanism. Wherein, a plurality of transfer bottle clamps 302 are arranged at equal intervals, and the distance between the central axes of two adjacent transfer bottle clamps 302 is the same as the distance between the central axes of two adjacent green body molding cavities, that is, each transfer bottle clamp 302 corresponds to a Tighten a preform or plastic bottle. Specifically, the second sliding mechanism includes a transfer slide 305, a transfer second slide rail 306 and a transfer second power device 308, and the transfer second slide rail 306 is arranged on the transfer frame 301 along the width direction, The transfer slide 305 is installed on the transfer second slide rail 306 and can slide back and forth along the transfer second slide rail 306, the power output end of the transfer second power device 308 is connected to the transfer slide seat 305 for driving the transfer slide 305 to slide back and forth along the second transfer slide 306 . Wherein, the transfer second power device 308 is installed on the transfer frame 301, and the transfer second power device 308 may adopt an air cylinder, an oil cylinder, a linear motor or other linear drive mechanism. In addition, the first sliding mechanism is slidably connected with the transfer slide 305, and when the transfer second power device 308 drives the transfer slide 305 to slide along the transfer second slide rail 306, the transfer slide 305 drives The first sliding mechanism and the transfer bottle clamp 302 slide along the width direction, so as to realize sending the material into or out of the processing station.

In addition, the first sliding mechanism specifically includes a transfer translation plate 303, a transfer first slide rail 304, a transfer connection plate 307 and a transfer first power device 309, and the transfer bottle clamps 302 are installed in a row on the transfer translation plate 303, the transfer first slide rail 304 is arranged on the second slide mechanism along the length direction, specifically installed on the transfer slide seat 305, and the transfer translation plate 303 is installed on the transfer first slide rail 304 and can slide back and forth along the transfer first slide rail 304, the transfer connection plate 307 is connected with the transfer translation plate 303, the power output end of the transfer first power device 309 is connected with the transfer connection plate 307 connection, used to drive the transfer connection plate 307 and drive the transfer translation plate 303 to slide back and forth along the transfer first slide rail 304 . When the transfer first power device 309 drives the transfer connection plate 307 to move along the length direction, the transfer connection plate 307 drives the transfer translation plate 303 to slide on the transfer first slide rail 304, thereby realizing the transfer of bottles. The clamp 302 moves between multiple processing stations to realize material transfer. Wherein, the transfer connection plate 307 and the transfer translation plate 303 are integrally connected, for example, the two are integrally formed, or both are welded and fixed; or, the transfer connection plate 307 and the transfer translation plate 303 Use a detachable fastening connection, for example by screw fastening. Wherein, the transfer first power device 309 adopts an air cylinder, an oil cylinder, a linear motor or other linear drive mechanism.

Optionally, the transfer bottle clamps 302 are arranged in groups, and the quantity of each group of transfer bottle clamps 302 is the same as the number of rows of materials to be transferred, that is, one transfer bottle clamp 302 correspondingly clamps a preform or plastic bottle, and the The transfer mechanism 300 includes a plurality of sets of transfer bottle clamps 302, each set of transfer bottle clamps 302 is assembled on a group of transfer translation plates 303, and the center axis spacing and arrangement quantity of each group of transfer bottle clamps 302 are the same, thereby facilitating Realize synchronous processing of multiple groups of materials. As preferably, the transfer mechanism 300 includes five sets of transfer bottle clamps 302, each set of transfer bottle clamps 302 is responsible for reciprocating translational movement between two adjacent processing stations, for example, one set of transfer bottle clamps 302 is responsible for the injection molding module 100 and the blank preheating module 400 for the transfer of preforms in rows, a set of transfer clamps 302 realize the transfer of preforms in rows between the blank preheating module 400 and the blowing module 200, a set of transfer clamps 302 Responsible for the transfer of rows of plastic bottles between the blowing module 200 and the filling module 500, a group of transfer bottle clamps 302 are responsible for the transfer of rows of plastic bottles between the filling module 500 and the sealing module 600, and a group of transfer bottle clamps 302 are responsible for The rows of finished products after sealing in the sealing module 600 are transferred out. Wherein, the action of multiple groups of transfer bottle clamps 302 entering into the processing station or exiting the processing station remains consistent, for example, when the transfer second power device 308 drives the transfer slide 305 on the transfer second slide rail 306 When sliding along the width direction, the first set of transfer bottle clamps 302 moves towards the direction of the injection molding station to hold the preform or take the preform away from the injection molding station, and simultaneously realizes the second set of transfer bottle clamps 302 towards the direction of the green body preheating station The clamped preform falls into the preheating station or exits the preheating station with the preform, and the third group of transfer bottle clamps 302 moves in the direction of the blowing station to make the preform fall into the blowing station. The bottle station or the plastic bottle exit the blowing station, and the fourth set of transfer bottle clamps 302 moves towards the filling station simultaneously to make the plastic bottle enter the filling station or bring the plastic bottle out of the filling station, Synchronously realize that the fifth group of transfer bottle clamps 302 moves towards the sealing station direction so that the plastic bottle enters the sealing station or withdraws from the sealing station with the plastic bottle. That is, each group of transfer bottle clamps 302 is carried out synchronously at the injection molding station, green body preheating station, bottle blowing station, filling station and sealing station, or each group of transfer bottle clips 302 described above is at the injection molding station , Green body preheating station, bottle blowing station, filling station and sealing station exit simultaneously.

It can be understood that in this embodiment, the green body preheating module 400 includes a preheating frame 401, a preheating auxiliary plate 402, a preheating linkage mechanism 403, a preheating first movable platen 404, a preheating fixed platen 405, The first preheating mold 406, the fixed preheating mold 407, the preheating slide rail and the preheating power mechanism 408; the preheating fixed template 405 is fixed on the preheating frame 401, and the preheating auxiliary plate 402 and the first movable template are preheated 404 is slidingly assembled on the preheating slide rail, the first preheating movable platen 404 is between the preheating auxiliary plate 402 and the preheating fixed platen 405, and the preheating link mechanism 403 is located between the preheating auxiliary plate 402 and the preheating first movable platen. Between the templates 404, the power output end of the preheating power mechanism 408 is connected to the preheating link mechanism 403; the first preheating mold 406 is fixed on the side of the preheating first movable template 404 facing the preheating fixed template 405, The fixed preheating mold 407 is fixed on the side of the preheating fixed template 405 facing the first preheating mold 406, and the first preheating mold 406 is relatively buckled with the fixed preheating mold 407 to form a row of blanks simultaneously. Hot rows of preheated chambers. The transfer mechanism 300 translates the rows of blanks output by the injection molding module 100 to the preheating station between the first preheating mold 406 and the fixed preheating mold 407, and drives the preheating link mechanism 403 to expand through the preheating power mechanism 408, And promote the preheating first movable template 404 to drive the first preheating mold 406 to the fixed preheating mold 407 on the preheating fixed template 405 to buckle and accommodate the green body, respectively to the first preheating mold 406 and the fixed preheating mold 407 A heating medium at a preset temperature is introduced into the heating medium circulation channel in the matrix to preheat the green body; after preheating for a preset time, the preheating link mechanism 403 is driven to fold and shrink by the preheating power mechanism 408, The first preheating mold 406 is relatively separated from the fixed preheating mold 407 to expose the rows of green bodies after preheating, and the rows of green bodies after preheating are transferred to the blowing module 200 of the next process through the transfer mechanism 300 Blow bottle. Optionally, Corinthian poles are used for the preheating slide rails. Optionally, the preheating auxiliary plate 402 can also be fixed on the preheating frame 401, and the preheating link mechanism 403 is driven by the preheating power mechanism 408, thereby controlling the preheating first movable template 404 to approach or move away from the preheating fixed plate. Template 405. Optionally, the preheating power mechanism 408 adopts a cylinder, an oil cylinder, a telescopic motor, a gear set driving mechanism, etc. or a similar driving mechanism, which can be driven in cooperation with the preheating linkage mechanism 403; it can also be directly driven by the preheating power mechanism 408.

Optionally, as shown in Figure 10 and Figure 11, in this embodiment, the green body preheating module 400 includes a preheating frame 401, a preheating auxiliary plate 402, a preheating linkage mechanism 403, a preheating first movable template 404, preheating the second movable template 409, preheating the fixed template 405, the first preheating mold 406, the second preheating mold 410, the fixed preheating mold 407, the preheating Corinthian column 411 and the preheating power mechanism 408; The heat-fixed template 405 is fixed on the preheating frame 401, and both sides of the preheated fixed template 405 are provided with a fixed preheating mold 407; preheating auxiliary plate 402, preheating the first movable template 404, and preheating the second movable template 409 Slidingly assembled on the preheating Corinthian column 411, a preheating link mechanism 403 is provided between the preheating auxiliary plate 402 and the first preheating movable template 404, and the power output end of the preheating power mechanism 408 is connected to the preheating connecting rod On the mechanism 403; the preheating first movable template 404 and the preheating second movable template 409 are respectively arranged on both sides of the preheating fixed template 405, and the side of the preheating first movable template 404 facing the preheating fixed template 405 is fixed with a first preheating The hot mold 406, preheating the second movable template 409 is fixed with the second preheating mold 410 on one side facing the preheating fixed template 405; There are rows of preheating cavities for simultaneous preheating of green bodies, and the second preheating mold 410 is engaged with the fixed preheating mold 407 to form rows of preheating cavities for simultaneously preheating rows of blanks. The transfer mechanism 300 translates the rows of blanks output by the injection molding module 100 to the first preheating station between the first preheating mold 406 and the fixed preheating mold 407 and between the second preheating mold 410 and the fixed preheating mold 407 The second preheating station between them drives the preheating link mechanism 403 to expand through the preheating power mechanism 408, and pushes the first movable template 404 for preheating to drive the first preheating mold 406 to the fixed preheating mold 405 on the preheating fixed template 405. The hot mold 407 buckles and accommodates the green body, and synchronously preheats the auxiliary plate 402 by the force of the preheating link mechanism 403 to drive the preheated second movable platen 409 to drive the second preheated mold 410 toward The fixed preheating mold 407 on the preheating fixed template 405 buckles and accommodates the green body, and passes into the heating medium circulation channel in the matrix of the first preheating mold 406, the fixed preheating mold 407 and the second preheating mold 410 respectively. The heating medium at the preset temperature, and then preheat the green body; after preheating for a preset time, the preheating linkage mechanism 403 is driven to fold and shrink by the preheating power mechanism 408, so that the first preheating mold 406 is synchronously It is relatively separated from the fixed preheating mold 407 and the second preheating mold 410 is relatively separated from the fixed preheating mold 407, and the rows of green bodies after preheating are exposed, and the rows of green bodies after preheating are transferred to the lower The bottle blowing module 200 of the first process performs bottle blowing. Optionally, the preheating power mechanism 408 adopts a cylinder, an oil cylinder, a telescopic motor, a gear set driving mechanism, etc. or a similar driving mechanism, which can be driven in cooperation with the preheating linkage mechanism 403; it can also be directly driven by the preheating power mechanism 408.

Optionally, as shown in Figure 12, in this embodiment, the body preheating module 400 includes a preheating frame 401, a preheating fixed template 405, a preheating movable template 412 and a preheating power mechanism 408; a preheating fixed template 405 is fixed on the preheating frame 401, and the preheating movable template 412 is slidably assembled on the preheating frame 401 through the preheating slide rail. A fixed preheating mold 407 is fixed on the side facing the preheating movable template 412, and a movable preheating mold 413 is fixed on a side of the preheating movable template 412 facing the preheating fixed template 405; Combined to form a preheating station. At the preheating station, when the fixed preheating mold 407 and the moving preheating mold 413 are in the open state, the transfer bottle clamp 302 is driven by the transfer second power device 308 to translate along the transfer first slide rail 304, and the rows of blanks are brought into the The preheating station is driven by the transfer first power device 309 to move forward along the transfer second slide rail 306, so that the rows of blanks are put in place. Then the preheating movable template 412 is clamped in place along the preheating slide rail under the action of the preheating power mechanism 408, and the preheating starts. After heating to the preset time, the preheating power mechanism 408 retreats and drives the preheating movable platen 412 to open the mold, transfers the first power device 309 to drive back, and the rows of blanks return to the center line of motion, ready to enter the next process.

As shown in Fig. 1, Fig. 13 and Fig. 14, in this embodiment, the filling module 500 includes a filling frame 501, a filling clamping bottle assembly 502 arranged on the filling frame 501 and a The filling system 503 on the frame 501, the filling and clamping bottle assembly 502 is used to clamp rows of plastic bottles during the filling operation, and the filling system 503 is used to synchronously fill the rows of plastic bottles solid material. When the transfer mechanism 300 transfers the rows of plastic bottles from the bottle blowing module 200 to the filling module 500, the filling and clamping bottle assembly 502 clamps the rows of plastic bottles, and then the filling system 503 transfers the row of plastic bottles to the row of plastic bottles. The bottle is filled with solid material synchronously. Wherein, the filling and clamping bottle assembly 502 includes a first filling movable splint 5021, a second filling movable splint 5022 and two filling bottle clamp driving devices 5023, and the first filling movable splint 5021 faces one side of the transfer mechanism 300. The side is provided with semicircular notches for forming filling stations. Multiple semicircular notches are arranged at intervals along the length direction of the first filling movable splint 5021, and multiple second filling movable splints 5022 are arranged along the length of the first filling movable splint. The length direction of 5021 can be arranged movably and the second filling movable splint 5022 is arranged in one-to-one correspondence with the semicircular notch. The power output end of the bottle clamp driving device 5023 is respectively connected to each second filling movable splint 5022 and drives each second filling movable splint 5022 to move synchronously, and the power output end of the other filling bottle clamp driving device 5023 is connected to the second filling movable splint 5022. A filling movable clamp 5021 drives the first filling movable clamp 5021 and multiple second filling movable clamps 5022 to move synchronously. The rows of plastic bottles are translated from the bottle blowing module 200 to the filling module 500 through the transfer mechanism 300 and enter each filling station respectively. The filling system 503 performs synchronous filling corresponding to each plastic bottle in the row of plastic bottles. After the filling is completed, the filling clamp bottle assembly 502 releases the filled row of plastic bottles, and the filled row of plastic bottles passes through the The transfer mechanism 300 is transferred to the next process as a whole. The bottle clamping action of the filling and clamping bottle assembly 502 is as follows: the row of plastic bottles is translated to the filling station by the transfer mechanism 300, and the first filling movable splint 5021 and multiple second filling movable splints are driven by two filling bottle clamp driving devices 5023. The two filling movable splints 5022 move synchronously, so that the semicircle notch and the arc notch are close to each other, and then the combination of the semicircle notch and the arc notch constitutes a hoop assembly for hooping the mouth of the plastic bottle, ensuring that the plastic bottle is Stability during the filling operation, and then, the transfer mechanism 300 exits the filling station, and then the quantitative filling is carried out into the plastic bottle through the filling system 503 at this time. After the filling is completed, the transfer mechanism 300 enters the filling station to clamp the rows of plastic bottles, and then the two filling bottle clamp driving devices 5023 drive the second filling, the first filling movable splint 5021 and the plurality of second filling clamps. The two filling splints 5022 move in reverse synchronously, so that the semicircle notch and the arc notch are separated from each other, so that the semicircle notch and the arc notch are disengaged, and then the transfer mechanism 300 drives the filled rows of plastic bottles Translational exit, and translational movement to the next station, while the next batch of plastic bottles in rows is translated from the blowing module 200 to the position of the filling module 500, thereby completing a batch of filling process. Optionally, the filling bottle clamp driving device 5023 adopts an air cylinder.

The filling system 503 includes a filling storage box 5031 and a screw conveyor 5034 connected to the output end of the filling storage box 5031. The screw conveyor 5034 is arranged in a one-to-one correspondence with the filling stations up and down. The filling storage box 5031 is used for storing solid powder materials, and the screw conveyor 5034 is used for synchronously filling the solid powder materials into rows of plastic bottles. After the rows of plastic bottles are moved in place, they are clamped and fixed by the filling and clamping bottle assembly 502, and the action of the screw conveyor 5034 is controlled to quantitatively output powder materials into the corresponding plastic bottles, and then stop the action, and the filling is completed. The filling of rows of plastic bottles takes place simultaneously.

Optionally, as shown in Figure 15, the filling system 503 includes a storage hopper 5035, a vibrating feeding device 5036 and a counting and unloading device 5037, the output end of the storage hopper 5035 is connected to the input end of the vibrating feeding device 5036, and the vibrating feeding device 5036 The output end of the device 5036 is connected to the input end of the counting and unloading device 5037, and the output end of the counting and unloading device 5037 is arranged toward the filling station. The storage hopper 5035 is used to store solid particle materials, and the vibrating feeding device 5036 Vibration is used to transport the solid particle material to the counting and feeding device 5037. The counting and feeding device 5037 is used to transport the solid particle material into the plastic bottle and control the amount of solid particles in the bottle. The vibrating feeding device 5036, the counting device The feeding device 5037 and the filling station are arranged in one-to-one correspondence. Wherein, the vibrating feeding device 5036 can adopt a flat vibrating feeder. After the rows of plastic bottles are moved in place, they are clamped and fixed by the filling and clamping bottle assembly 502, and the vibrating feeding device 5036 is controlled to vibrate and output the granular materials in the direction of the corresponding plastic bottles, and the counting and unloading device 5037 counts and outputs to In the corresponding plastic bottle, the counting and feeding device 5037 outputs a preset amount of granular materials, and then the counting and feeding device 5037 and the vibrating feeding device 5036 stop working, and the filling is completed. The filling of rows of plastic bottles takes place simultaneously.

Optionally, as shown in FIG. 16, the filling system 503 includes a filling storage box 5031, a filling delivery pipe 5032 connected to the output end of the filling storage box 5031, and a filling delivery pipe 5032 arranged on the filling delivery pipe 5032. The filling valve 5033, the filling conveying pipe 5032 and the filling station are arranged in a one-to-one correspondence up and down. After the rows of plastic bottles are moved in place, they are clamped and fixed by the filling and clamping bottle assembly 502, and the filling valve 5033 is controlled to open and close after quantitative output of liquid materials. The filling is completed, and the filling of the rows of plastic bottles is carried out synchronously .

As shown in Figure 17, in this embodiment, the sealing module 600 includes a sealing frame 601, a sealing clip bottle assembly 602 arranged on the sealing frame 601, and a sealing system 603 arranged on the sealing frame 601, wherein, The sealing and clamping bottle assembly 602 is used for clamping the entire row of plastic bottles during the sealing operation, and the sealing system 603 is used for synchronously sealing the entire row of plastic bottles.

It can be understood that the sealing clip bottle assembly 602 includes a first sealing movable splint, a second sealing movable splint and two sealing bottle clamp driving devices, and the first sealing movable splint is provided with a semicircle for forming a sealing station on the side facing the transfer mechanism 300 Notches, a plurality of semicircular notches are arranged at intervals along the length direction of the first sealing movable splint, a plurality of second sealing movable splints are movably arranged along the length direction of the first sealing movable splint and the second sealing movable splint and the semicircular groove The mouths are arranged in one-to-one correspondence, the second sealing movable splint is provided with a circular arc notch on the side facing the corresponding semicircular notch, and the power output end of a sealing bottle clamp driving device is respectively connected to each second sealing movable splint and drives each second sealing movable splint. The sealing movable splints move synchronously, and the power output end of the other bottle clamp driving device is connected to the first sealing movable splints and drives the first sealing movable splints and multiple second sealing movable splints to move synchronously. The transfer mechanism 300 translates the filled rows of plastic bottles to the sealing station of the sealing module 600, and the sealing clamp assembly 602 clamps each plastic bottle synchronously. The corresponding plastic bottles are sealed, and after the sealing is completed, the transfer mechanism 300 enters the sealing station to output the finished products in rows. The bottle clamping action of the sealing and clamping bottle assembly 602 is as follows: the transfer mechanism 300 translates the rows of plastic bottles to the sealing station, and drives the first sealing movable splint and multiple second sealing movable splints to move synchronously through two sealing and clamping bottle driving devices , so that the semicircle notch and the arc notch are close to each other, and then the semicircle notch and the arc notch are combined to form a hoop assembly for the hoop at the mouth of the plastic bottle, ensuring the stability of the plastic bottle during the sealing operation. Then, the transfer mechanism 300 exits the sealing station, and at this time, the plastic bottle is sealed via the sealing system 603 . After the sealing is completed, the transfer mechanism 300 enters the sealing station to clamp rows of plastic bottles, and the two sealing bottle clamp driving devices drive the first sealing movable splint and multiple second sealing movable splints to move in reverse synchronously to make the semicircular groove The mouth is disengaged from the arc notch, and then the transfer mechanism 300 drives the sealed rows of finished products to move out in translation, and move to the next station or directly output, and at the same time the rows of plastic bottles of the next batch are discharged from the filling module 500 translates to the sealing module 600 position, thereby completing a batch of sealing process. Optional sealing bottle clamp driving device adopts air cylinder. The sealing and clamping bottle assembly 602 is similar in structure and working principle to the filling and clamping bottle assembly 502 .

In this embodiment, the sealing system 603 is a gland type sealing mechanism, a screw cap type sealing mechanism or a welding cap type sealing mechanism. Among them, the cap-type sealing mechanism assembles the bottle cap on the bottle mouth in an interference-fit manner by pressing down, and then completes the sealing of the plastic bottle. The screw cap type sealing mechanism presses the bottle cap on the bottle mouth, then drives the bottle cap to rotate, and realizes the assembly of the bottle cap and the bottle mouth through threaded cooperation, and then completes the sealing of the plastic bottle. The welding cap sealing mechanism heats the inner wall of the bottle cap and/or the outer wall of the bottle mouth to the preset stability and predetermined time, and then presses the bottle cap on the bottle mouth and cools down to complete the heat fusion of the bottle cap and the bottle mouth Welding assembly, and then complete the sealing of plastic bottles.

Specifically, as shown in Fig. 18 and Fig. 19, the capping type sealing mechanism includes a first capping power mechanism 6031b, a second capping power mechanism 6032b, a capping slide rail 6033b, a capping connecting plate 6034b, a capping Take the capping rod 6035b and the capping frame 6036b, the fixed end of the first capping power mechanism 6031b is installed on the capping frame 6036b, and the capping frame 6036b is installed on the sealing frame 601 , the movable end of the first capping power mechanism 6031b is connected to the fixed end of the second capping power mechanism 6032b, and the gland connecting plate 6034b is respectively connected to the movable end, the second capping power mechanism 6032b, The gland is connected with the cap rod 6035b, the gland slide rail 6033b is arranged on the gland frame 6036b, the gland connecting plate 6034b is slidingly matched with the gland slide rail 6033b, and the first gland The power mechanism 6031b and the second capping power mechanism 6032b are used to drive the capping connecting plate 6034b to slide up and down along the capping slide rail 6033b. Optionally, the first capping power mechanism 6031b and the second capping power mechanism 6032b adopt linear motion mechanisms such as cylinders, electric telescopic rods, and linear motors. The action process of the gland-type sealing mechanism is as follows: the rows of plastic bottles are translated from the filling module 500 to the sealing module 600 through the transfer mechanism 300 and enter each sealing station respectively, and the rows of plastic bottles are synchronously aligned by the sealing clamping bottle assembly 602. The plastic bottle is clamped, supported and fixed, and the first capping power mechanism 6031b is controlled to drive the second capping power mechanism 6032b, the capping connecting plate 6034b and the capping and capping lever 6035b to slide downward. The cap removal rod 6035b is used to remove the cap. At this time, a preset distance is maintained between the lower plane of the plastic cap and the upper plane of the bottle mouth of the plastic bottle, and then the second capping power mechanism 6032b is controlled to drive the gland connecting plate 6034b, the cap-removing rod 6035b and the plastic cap continue to slide downward, and the bottle cap is assembled on the bottle mouth with an interference fit by pressing down, thereby completing the sealing of the plastic bottle. Finally, control the first capping power mechanism 6031b and the second capping power mechanism 6032b to drive the capping connecting plate 6034b and the capping and capping lever 6035b to slide upward to the initial position, waiting for the capping and sealing operation of the next batch of plastic bottles. Wherein, the cap-taking lever 6035b clamps the plastic cover by means of interference fit. For example, the cap-taking lever 6035b is a hollow rod whose inner hole size is slightly smaller than the diameter of the plastic cover. Take the downward movement of the cover rod 6035b, and press the plastic cover into the gland and get the cover rod 6035b. In addition, the cap-taking rod 6035b can also use the effect of pneumatic suction to suck the plastic cap. For example, the cap-taking rod 6035b is a hollow rod, and the air in the gland-taking rod 6035b is sucked away by an external fan, so that The inside of the capping and capping rod 6035b is in a negative pressure state, so that the plastic cap can be sucked. Wherein, the first capping power mechanism 6031b, the second capping power mechanism 6032b, the capping slide rail 6033b, the capping connecting plate 6034b, the capping and capping rod 6035b are arranged corresponding to the capping and sealing stations one by one.

Optionally, the linear injection-blow-fill-seal integrated plastic bottle packaging equipment further includes a cap feeding module 800 arranged behind the sealing module 600 along the linear arrangement direction, and the cap feeding module 800 is used to provide The capping module 600 delivers plastic caps. As shown in Figure 20, the cap feeding module 800 includes a vibration sorting device 801, a cap feeding plate 802, and a cap feeding power mechanism 803. The vibration sorting device 801 is used to store plastic caps and vibrate a plurality of plastic caps Output after sorting, the cover sending plate 802 is arranged at the output end of the vibration sorting device 801 for receiving the sorted plastic covers, and the power output end of the cover sending power mechanism 803 is connected to the cover sending plate 802 , used to drive the cap delivery plate 802 to move to receive the plastic caps one by one and transport the plastic caps to the sealing module 600 . When the sealing system 603 is at the highest position, the cap feeding power mechanism 803 drives the cap feeding plate 802 to move, and the moving direction is opposite to the conveying direction of plastic bottles, and the cap feeding plate 802 receives the caps one by one during the moving process The plastic caps output by the vibration sorting device 801, wherein, the cover sending plate 802 is evenly spaced with a plurality of grooves, and the multiple plastic caps output by the vibration sorting device 801 are sequentially sent into the plurality of grooves, when After the cap feeding power mechanism 803 moves in place, the sealing system 603 descends to remove the cap, and then the cap feeding power mechanism 803 drives the cap feeding plate 802 to move back, waiting for the next delivery of plastic caps. Wherein, the vibration sorting device 801 adopts an existing vibrating disk sorting machine or a vibrating disk sorting machine, so the specific structure and working principle will not be repeated here. The cap sending power mechanism 803 can adopt an air cylinder, an oil cylinder, a telescopic motor, a gear set driving mechanism, etc. or a similar driving mechanism. It can be understood that the vibration sorting device 801 , the cap feeding plate 802 and the cap feeding power mechanism 803 are all installed on the cap feeding frame.

In this embodiment, the laminar flow hood 700 includes at least one of a transparent observation window, a material replenishment port, and an inspection port. A transparent observation window is arranged to facilitate the observation of the working process of the linear injection, blowing, filling and sealing plastic bottle packaging equipment, which is conducive to timely finding and troubleshooting of problems. The material replenishment port is arranged to replenish various materials, such as injection molding raw materials, filling raw materials, bottle caps, etc., to the linear injection, blowing, filling and sealing integrated plastic bottle packaging equipment. The inspection port is arranged to be used for daily equipment maintenance even if there is a problem with the equipment, even if it is maintained, replaced, or repaired.

The above descriptions are only preferred embodiments of the present invention, and are not intended to limit the present invention. For those skilled in the art, the present invention may have various modifications and changes. Any modifications, equivalent replacements, improvements, etc. made within the spirit and principles of the present invention shall be included within the protection scope of the present invention.

Claims

A linear plastic bottle packaging equipment integrating injection, blowing, filling and sealing is characterized in that it includes an injection molding module (100), a bottle blowing module (200), a filling module (500) and a sealing module ( 600), the injection molding module (100) is used for injection molding to form rows of preforms, and the bottle blowing module (200) is used for blow molding rows of preforms to form rows of plastic bottles, and the filling module (500) uses To fill the rows of plastic bottles with materials, the sealing module (600) is used to seal the rows of plastic bottles after filling, and also includes a method for sealing the rows of materials output by the injection molding module (100). Translating and sequentially entering the blowing module (200), the filling module (500) and the sealing module (600) and then outputting the transfer mechanism (300) in rows of products;

The sealing module (600) includes a sealing frame (601), a sealing clip bottle assembly (602) arranged on the sealing frame (601) and a sealing system (603) arranged on the sealing frame (601), so The sealing and clamping bottle assembly (602) is used to clamp the entire row of plastic bottles during the sealing operation, and the sealing system (603) is used to perform synchronous sealing operations on the entire row of plastic bottles, wherein the sealing system (603 ) includes the first capping power mechanism (6031b), the second capping power mechanism (6032b), the capping slide rail (6033b), the capping connecting plate (6034b), the capping and capping lever (6035b) and the capping machine frame (6036b), the fixed end of the first capping power mechanism (6031b) is installed on the capping frame (6036b), and the capping frame (6036b) is installed on the sealing frame (601 ), the movable end of the first capping power mechanism (6031b) is connected to the fixed end of the second capping power mechanism (6032b), and the gland connecting plate (6034b) is respectively connected to the second capping power mechanism The movable end of the capping power mechanism (6032b) and the capping are connected with the capping rod (6035b), the capping slide rail (6033b) is arranged on the capping frame (6036b), and the capping connecting plate (6034b ) is slidingly matched with the gland slide rail (6033b), and the first capping power mechanism (6031b) and the second capping power mechanism (6032b) are used to drive the gland connecting plate (6034b) along the The gland slide rail (6033b) slides up and down.
The linear plastic bottle packaging equipment integrating injection, blowing, filling and sealing according to claim 1, characterized in that a body preheating module ( 400), the injection molding module (100), the body preheating module (400) and the bottle blowing module (200) are arranged in sequence in a straight line, and the injection molding module (100) passes through the transfer mechanism ( 300) Translate the rows of blanks output by injection molding into the blank preheating module (400) for preheating, and then translate them into the blowing module (200) for bottle blowing.
The linear injection, blowing, filling and sealing integrated plastic bottle packaging equipment according to claim 2, characterized in that, the body preheating module (400) includes a preheating frame (401), a preheating auxiliary plate (402) , preheating link mechanism (403), preheating first moving template (404), preheating fixed template (405), first preheating mold (406), fixed preheating mold (407), preheating slide rail and The preheating power mechanism (408), the preheating fixed template (405) is fixed on the preheating frame (401), the preheating auxiliary plate (402), the preheating first movable template (404 ) is slidingly assembled on the preheating slide rail, the first preheating movable template (404) is between the preheating auxiliary plate (402) and the preheating fixed template (405), and the preheating connecting rod The mechanism (403) is located between the preheating auxiliary plate (402) and the first preheating movable template (404), and the power output end of the preheating power mechanism (408) is connected to the preheating connecting rod mechanism (403), the first preheating mold (406) is fixed on the side of the first preheating movable template (404) facing the preheating fixed template (405), and the fixed preheating mold (407) fixed on the side of the preheating fixed template (405) facing the first preheating mold (406), the first preheating mold (406) and the fixed preheating mold (407) Rows of preheating cavities for simultaneously preheating rows of billets are formed by buckling relative to each other.
The linear injection, blowing, filling and sealing integrated plastic bottle packaging equipment according to claim 2, characterized in that, the body preheating module (400) includes a preheating frame (401), a preheating auxiliary plate (402) , preheating link mechanism (403), preheating the first movable platen (404), preheating the second movable platen (409), preheating the fixed platen (405), the first preheating mold (406), the second preheating Thermal mold (410), fixed preheating mold (407), preheating Corinthian column (411) and preheating power mechanism (408), described preheating fixed template (405) is fixed on described preheating frame (401 ), the fixed preheating mold (407) is provided on both sides of the preheating fixed template (405), the preheating auxiliary plate (402), the first preheating movable template (404), the The second preheating movable template (409) is slidingly assembled on the preheating Corinthian column (411), and a preheating auxiliary plate (402) is provided between the preheating first movable template (404). The preheating link mechanism (403), the power output end of the preheating power mechanism (408) is connected to the preheating link mechanism (403), the preheating first movable template (404) and The preheated second movable template (409) is respectively arranged on both sides of the preheated fixed template (405), and the preheated first movable template (404) is fixed toward one side of the preheated fixed template (405) There is the first preheating mold (406), the second preheating mold (410) is fixed on the side of the preheating second movable template (409) facing the preheating fixed template (405), the The first preheating mold (406) is relatively fastened with the fixed preheating mold (407) to form a row of preheating chambers for simultaneously preheating rows of green bodies, and the second preheating mold (410) The rows of preheating cavities for simultaneous preheating of rows of blanks are formed by fastening relative to the fixed preheating mold (407).
The linear injection, blowing, filling and sealing integrated plastic bottle packaging equipment according to claim 1, characterized in that, the sealing and clamping bottle assembly (602) includes a first sealing movable splint, a second sealing movable splint and a sealing bottle clamp drive device, the side of the first sealing movable splint facing the transfer mechanism (300) is provided with a semicircular notch for forming a sealing station, a plurality of semicircular notches are arranged at intervals along the length direction of the first sealing movable splint, and a plurality of second The sealing movable splint is movably arranged along the length direction of the first sealing movable splint and the second sealing movable splint is arranged in one-to-one correspondence with the semicircular notch, and the second sealing movable splint is provided with an arc groove on the side facing the corresponding semicircular notch The power output end of a sealing bottle clamp driving device is respectively connected to each second sealing movable splint and drives each second sealing movable splint to move synchronously, and the power output end of the other sealing bottle clamp driving device is connected to the first sealing movable splint And drive the first sealing splint and a plurality of second sealing movable splints to move synchronously, so that the combination of the semicircular notch and the arc notch constitutes a hoop assembly for hooping the mouth of the plastic bottle.
The linear injection, blowing, filling and sealing integrated plastic bottle packaging equipment according to claim 1, characterized in that, the transfer mechanism (300) includes a transfer frame (301), a transfer bottle clamp (302) and a sliding mechanism, the The sliding mechanism is slidably connected to the transfer frame (301), the transfer bottle clamp (302) is connected to the sliding mechanism, the transfer bottle clamp (302) is used for clamping materials, and the sliding The mechanism is used to drive the transfer bottle clamp (302) to move linearly in the width direction or the length direction to complete the material transfer.
The linear injection, blowing, filling and sealing integrated plastic bottle packaging equipment according to claim 6, wherein the sliding mechanism comprises a first sliding mechanism and a second sliding mechanism, and the second sliding mechanism is slidable along the width direction connected to the transfer frame (301), the first slide mechanism is slidably connected to the second slide mechanism along the length direction, and the transfer bottle clamps (302) are arranged in rows and assembled on the first slide mechanism.
The linear injection, blowing, filling and sealing integrated plastic bottle packaging equipment according to claim 7, characterized in that, the second sliding mechanism includes a transfer slide seat (305), a transfer second slide rail (306) and a transfer second The power device (308), the transfer second slide rail (306) is arranged on the transfer frame (301) along the width direction, the transfer slide seat (305) is installed on the transfer second slide rail (306) ) and can slide back and forth along the transfer second slide rail (306), the power output end of the transfer second power device (308) is connected with the transfer slide seat (305) for driving the transfer slide The seat (305) slides back and forth along the second transfer slide rail (306).
The linear injection, blowing, filling and sealing integrated plastic bottle packaging equipment according to claim 7, characterized in that, the first sliding mechanism includes a transfer translation plate (303), a transfer first sliding rail (304), a transfer connecting plate (307) and transfer the first power unit (309), the transfer bottle clamps (302) are installed in a row on the transfer translation plate (303), and the transfer first slide rail (304) is arranged along the length direction On the second sliding mechanism, the transfer translation plate (303) is installed on the transfer first slide rail (304) and can slide back and forth along the transfer first slide rail (304), and the transfer connection plate (307) is connected with the transfer translation plate (303), and the power output end of the transfer first power device (309) is connected with the transfer connection plate (307) for driving the transfer connection plate (307) And drive the transfer translation plate (303) to slide back and forth along the first transfer slide rail (304).
The linear injection, blowing, filling and sealing integrated plastic bottle packaging equipment according to claim 1 is characterized in that it also includes a plastic bottle for forming a sterile sealed space and accommodating the injection molding module (100), the blowing bottle module (200 ), the laminar flow hood (700) of the filling module (500), the sealing module (600) and the transfer mechanism (300).