High efficiency multi-mode press

By designing a multi-mold press, using a perforated plate circular mold and a hook mechanism, the problem of low efficiency in single-mold presses was solved, enabling efficient and continuous pressing of multiple materials and meeting the high-efficiency production needs of industrial production.

CN224335151UActive Publication Date: 2026-06-09SHANGHAI BEYOND MACHINERY

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SHANGHAI BEYOND MACHINERY
Filing Date
2025-06-19
Publication Date
2026-06-09

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Abstract

This utility model provides a high-efficiency multi-mold press, relating to the technical field of high-efficiency multi-mold presses. It includes: a press body, with an internal extrusion mechanism. A circular mold is located at the bottom of the extrusion mechanism, and a base is fixedly connected to the bottom of one of the circular molds. Hook mechanisms are provided on both sides of the circular mold. The extrusion mechanism includes a pressure plate A, with a pressure plate B at the bottom of pressure plate A, and a strong spring sleeved on the top of pressure plate B. This utility model, by setting a circular mold integrally formed from a perforated plate, allows the material placed inside the circular mold to be pressed and dehydrated. Simultaneously, to facilitate demolding, the taper of the circular mold is set to 1.5°~7°, allowing multiple circular molds to be nested together for efficient material pressing.
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Description

Technical Field

[0001] This utility model relates to the field of high-efficiency multi-mold press technology, and in particular to a high-efficiency multi-mold press. Background Technology

[0002] In modern industrial production, presses are widely used in the processing of various materials, such as food, chemicals, and pharmaceuticals.

[0003] However, most existing presses use a single-mold pressing method, which greatly limits the improvement of production efficiency. Each pressing operation can only form one piece of material. After completing one pressing cycle, the equipment must be stopped to load and unload the next set of molds. This intermittent production mode wastes a lot of time and equipment resources and cannot meet the needs of modern industrial production for efficient and continuous production. For some special materials, such as those that require long-term continuous pressing to achieve dehydration and shaping, traditional pressing equipment is even more inadequate. Utility Model Content

[0004] The purpose of this invention is to address the shortcomings of low pressing efficiency in existing single-mold presses and to provide a high-efficiency multi-mold press.

[0005] To achieve the above objectives, the present invention adopts the following technical solution: a high-efficiency multi-mold press, comprising: a press body, wherein a pressing mechanism is provided inside the press body, a circular mold is provided at the bottom of the pressing mechanism, a base is fixedly connected to the bottom of one of the circular molds, and hook mechanisms are provided on both sides of the circular mold; the pressing mechanism includes a pressure plate A, a pressure plate B is provided at the bottom of the pressure plate A, a strong spring is sleeved on the top of the pressure plate B, a spring-loaded buckle is sleeved inside the pressure plate A, the spring-loaded buckle is rotatably connected to the pressure plate A, and the hook mechanism includes a hook rod, a hook sleeve is sleeved on the outer surface of the hook rod, the hook rod and the hook sleeve are slidably connected, and a compression spring is provided inside the hook sleeve.

[0006] In a preferred embodiment, a baffle A is fixedly connected to the bottom of the pressure plate A.

[0007] A baffle tube B is fixedly connected to the top of plate B. The two ends of the strong spring are fixedly connected to the outer surfaces of pressure plate A and pressure plate B, respectively. An O-ring is provided in the mounting groove opened on the baffle tube A.

[0008] In a preferred embodiment, the O-ring is slidably connected to the retaining tube A, and a return spring is provided on one side of the spring-loaded block. The two ends of the return spring are respectively fixedly connected to the outer surfaces of the spring-loaded block and the retaining tube A.

[0009] In a preferred embodiment, a spring-loaded fastener is fitted inside the pressure plate A, and the spring-loaded fastener is fixedly connected to the pressure plate A by bolts.

[0010] In a preferred embodiment, one end of the compression spring is sleeved on the suspension column provided inside the hook sleeve, and the other end of the compression spring is fixedly connected to the outer surface of one end of the hook rod.

[0011] In a preferred embodiment, a double-ended stud is fitted inside the hook sleeve, and the double-ended stud is threadedly connected to the hook sleeve.

[0012] In a preferred embodiment, the double-ended stud is sleeved inside the base, and the double-ended stud is threadedly connected to the base.

[0013] Compared with the prior art, the advantages and positive effects of this utility model are as follows:

[0014] This invention utilizes a circular mold, integrally formed from a perforated plate, to allow material placed within the mold to be pressed and dehydrated. To facilitate demolding, the circular mold has a taper of 1.5° to 7°, enabling multiple circular molds to be nested together for efficient material pressing. A pressing mechanism is also included, allowing the pressure generated by the press's power unit to be transmitted to the circular mold, thus pressurizing the material within. Furthermore, the pressing mechanism securely engages with a hook mechanism, preventing it from detaching from the topmost circular mold and ensuring a stable and safe pressing process. Attached Figure Description

[0015] Figure 1 is a structural schematic diagram of a high-efficiency multi-mold press provided by this utility model.

[0016] Figure 2 is a perspective view of a high-efficiency multi-mold press provided by this utility model.

[0017] Figure 3 is a schematic diagram of the installation of a circular mold in a high-efficiency multi-mold press provided by this utility model.

[0018] Figure 4 is a schematic diagram of the installation of a powerful spring in a high-efficiency multi-mold press provided by this utility model.

[0019] Figure 5 is a schematic diagram of bolt installation for a high-efficiency multi-mode press provided by this utility model.

[0020] Figure 6 is a schematic diagram of the compression spring installation of a high-efficiency multi-mode press provided by this utility model.

[0021] Legend:

[0022] 1. Press body; 21. Extrusion mechanism; 202. Circular mold; 203. Base; 24. Hook mechanism; 2011. Pressure plate A; 2012. Pressure plate B; 2013. Baffle tube A;

[0023] 2014, B-type retainer; 2015, high-strength spring; 2016, O-ring seal; 2017, spring-loaded buckle block; 2018, return spring; 2019, spring-loaded buckle component; 2041, hook rod; 2042, compression spring; 2043, hook sleeve; 2044, double-ended stud. Detailed Implementation

[0024] The technical solutions of the present utility model will be clearly and completely described below with reference to the accompanying drawings of the embodiments. Obviously, the described embodiments are only some embodiments of the present utility model, and not all embodiments. Based on the embodiments of the present utility model, all other embodiments obtained by those of ordinary skill in the art without creative effort are within the protection scope of the present utility model.

[0025] Example 1

[0026] As shown in Figure 1- Figure 6 As shown, this utility model provides a technical solution: a high-efficiency multi-mold press, including: a press body 1, an extrusion mechanism 21 inside the press body 1, a circular mold 202 at the bottom of the extrusion mechanism 21, a base 203 fixedly connected to the bottom of one of the circular molds 202, hook mechanisms 24 on both sides of the circular mold 202, the extrusion mechanism 21 including a pressure plate A 2011, a pressure plate B 2012 at the bottom of the pressure plate A 2011, a strong spring 2015 sleeved on the top of the pressure plate B 2012, a spring-loaded buckle 2017 sleeved inside the pressure plate A 2011, the spring-loaded buckle 2017 rotatably connected to the pressure plate A 2011, and the hook mechanism 24 including a hook rod 2041, a hook sleeve 2043 sleeved on the outer surface of the hook rod 2041, the hook rod 2041 and the hook sleeve 2043 slidably connected, the hook sleeve 2043... An internal compression spring 2042 is provided. A stop tube A2013 is fixedly connected to the bottom of the pressure plate A2011, and a stop tube B2014 is fixedly connected to the top of the pressure plate B2012. A strong spring 2015 is also provided.

[0027] Both ends are fixedly connected to the outer surfaces of pressure plate A2011 and pressure plate B2012, respectively. An O-ring 2016 is provided in the mounting groove on the baffle tube A2013. The O-ring 2016 is slidably connected to the baffle tube A2013. A return spring 2018 is provided on one side of the spring-loaded block 2017. Both ends of the return spring 2018 are fixedly connected to the outer surfaces of the spring-loaded block 2017 and the baffle tube A2013, respectively. A spring-loaded fastener 2019 is sleeved inside the pressure plate A2011. The spring-loaded fastener 2019 is fixedly connected to the pressure plate A2011 by bolts.

[0028] In this embodiment, by setting multiple circular molds 202, the press body 1 can process a larger quantity or different types of materials simultaneously, resulting in higher pressing efficiency. A pressure plate A2011 is provided, with baffle tube A2013 fixedly connected to it. A pressure plate B2012 is also provided, with baffle tube B2014 fixedly connected to it. Baffle tubes A2013 and B2014 can be fitted together with the pressure plates A2011 and B2012, forming a closed space. This prevents the strong spring 2015 from being affected by external factors. An O-ring seal 2016 is provided to maintain the seal at the connection between baffle tubes A2013 and B2014, preventing external liquids from seeping into them. Inside, a spring-loaded latch 2017 is provided, which is sleeved on a round pin provided inside the stop tube A2013. The spring-loaded latch 2017 can be flipped and adjusted so that it can engage with the hook rod 2041. At the same time, a return spring 2018 is provided so that the flipped spring-loaded latch 2017 can automatically return to its original position and maintain the stability of the engagement between the spring-loaded latch 2017 and the hook rod 2041.

[0029] Example 2

[0030] As shown in Figures 1-6, one end of the compression spring 2042 is sleeved on the suspension column inside the hook sleeve 2043, and the other end of the compression spring 2042 is fixedly connected to the outer surface of one end of the hook rod 2041. A double-ended stud 2044 is sleeved inside the hook sleeve 2043 and is threaded to the hook sleeve 2043. The double-ended stud 2044 is sleeved inside the base 203 and is threaded to the base 203.

[0031] In this embodiment, by providing a hook rod 2041 with a slot on it that matches the spring-loaded latch 2017, the spring-loaded latch 2017 can be precisely engaged inside the hook rod 2041. Simultaneously, a compression spring 2042 is provided and placed inside the hook sleeve 2043. Therefore, when the compression spring 2042 is compressed, it will not...

[0032] In the event of twisting, the elastic force of the compression spring 2042 can act on the hook rod 2041 as much as possible, allowing the hook rod 2041 to return to its original position upwards. This ensures that the hook rod 2041 is always engaged with the spring-loaded latch block 2017. A double-ended stud 2044 is provided, and the double-ended stud 2044 is threadedly connected to both the hook sleeve 2043 and the base 203. This allows the double-ended stud 2044 to be securely connected to the base 203. Furthermore, the hook sleeve 2043 is used to adjust the height of the hook rod 2041, enabling the hook rod 2041 to engage smoothly with the spring-loaded latch block 2017.

[0033] Working principle:

[0034] As shown in Figure 1- Figure 6 As shown, when using this utility model, the double-ended stud 2044 can be first connected to the base.

[0035] 203 Threaded connection until the hook sleeve 2043 is fitted onto the outer surface of one end of the double-ended stud 2044, and the hook sleeve 2043 rotates on the outer surface of the double-ended stud 2044 until the working height of the hook rod 2041 is suitable. Then, a certain number of circular molds 202 are stacked together, and the pressure plate B2012 is fitted into the inside of the topmost circular mold 202. At this time, the spring-loaded block 2017 is slightly flipped so that the other end of the spring-loaded block 2017 can be placed in the slot of the hook rod 2041. When the spring-loaded block 2017 is flipped, it can compress the return spring 2018, so that the return spring 2018 generates elastic force. Then, when the spring-loaded block 2017 is reset, the elastic force of the return spring 2018 will tightly lock the spring-loaded block 2017 into the inside of the hook rod 2041. Then, the press body 1 is started. At this time, the press body 1 The power component gradually approaches the pressure plate A2011, which in turn compresses the strong spring 2015, causing it to generate elastic force. The strong spring 2015 then transmits pressure to the pressure plate B2012, which in turn compresses the multiple circular molds 202 at its bottom. Since the circular molds 202 are conical, the material inside them is squeezed. Simultaneously, the hook rod 2041 compresses the compression spring 2042 located inside the hook sleeve 2043, causing it to generate elastic force. This elastic force keeps the hook rod 2041 engaged with the spring-loaded block 2017. At this time, the moisture inside the material can be discharged through the slots on the circular molds 202 and leak out through the drain pipe of the press body 1. Thus, the press body 1... This allows for the simultaneous pressing of materials within multiple circular molds 202.

[0036] The above description is merely a preferred embodiment of this utility model and is not intended to limit the utility model in any other way. Any person skilled in the art may utilize the technical content disclosed above.

[0037] Equivalent embodiments with alterations or modifications can be applied to other fields. However, any simple modifications, equivalent changes, and modifications made to the above embodiments based on the technical essence of this utility model, without departing from the scope of the present utility model's technical solution, shall still fall within the protection scope of this utility model's technical solution.

Claims

1. A high-efficiency multi-mold press, characterized in that, include: The press body (1) has an internal extrusion mechanism (21). A circular mold (202) is located at the bottom of the extrusion mechanism (21). A base (203) is fixedly connected to the bottom of one of the circular molds (202). Hook mechanisms (24) are located on both sides of the circular mold (202). The extrusion mechanism (21) includes a pressure plate A (2011). A pressure plate B (2012) is located at the bottom of the pressure plate A (2011). A strong spring (2015) is sleeved on the top of the pressure plate A (2011), and a spring buckle block (2017) is sleeved inside the pressure plate A (2011). The spring buckle block (2017) is rotatably connected to the pressure plate A (2011). The hook mechanism (24) includes a hook rod (2041). A hook sleeve (2043) is sleeved on the outer surface of the hook rod (2041). The hook rod (2041) and the hook sleeve (2043) are slidably connected. A compression spring (2042) is provided inside the hook sleeve (2043).

2. The high-efficiency multi-mold press according to claim 1, characterized in that: The bottom of the pressure plate A (2011) is fixedly connected to the baffle tube A (2013), the top of the pressure plate B (2012) is fixedly connected to the baffle tube B (2014), the two ends of the strong spring (2015) are respectively fixedly connected to the outer surfaces of the pressure plate A (2011) and the pressure plate B (2012), and an O-ring seal (2016) is provided in the mounting groove opened on the baffle tube A (2013).

3. The high-efficiency multi-mold press according to claim 2, characterized in that: The O-ring (2016) is slidably connected to the retaining tube A (2013). One side of the spring-loaded block (2017) is provided with a return spring (2018). The two ends of the return spring (2018) are respectively fixedly connected to the outer surfaces of the spring-loaded block (2017) and the retaining tube A (2013).

4. The high-efficiency multi-mold press according to claim 3, characterized in that: The pressure plate A (2011) is fitted with a spring fastener (2019), which is fixedly connected to the pressure plate A (2011) by bolts.

5. The high-efficiency multi-mold press according to claim 1, characterized in that: One end of the compression spring (2042) is sleeved on the suspension column inside the hook sleeve (2043), and the other end of the compression spring (2042) is fixedly connected to the outer surface of one end of the hook rod (2041).

6. The high-efficiency multi-mold press according to claim 5, characterized in that: The hook sleeve (2043) is internally fitted with a double-ended stud (2044), and the double-ended stud (2044) is threadedly connected to the hook sleeve (2043).

7. The high-efficiency multi-mold press according to claim 6, characterized in that: The double-ended stud (2044) is sleeved inside the base (203), and the double-ended stud (2044) is threadedly connected to the base (203).