A mold frame for casting processing
By designing multiple placement compartments and support mechanisms on the mold rack, the problems of inconvenience in picking up and placing molds and insufficient structural strength during use are solved, enabling stable lifting and safe movement of casting molds, and improving the ease of use and safety of the mold rack.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- CHONGQING TONGDA MOLD CO LTD
- Filing Date
- 2025-09-05
- Publication Date
- 2026-06-30
AI Technical Summary
Existing mold racks are inconvenient for placing and removing inner molds during use, and are prone to deformation or overturning due to insufficient structural strength, posing safety hazards.
The design incorporates multiple placement grids and support mechanisms, including load-bearing and support mechanisms. Stable movement and support of the casting mold are achieved through guide components and linear modules, enhancing the stability and safety of the mold frame.
It facilitates the lifting and placement of casting molds, improves the ease of use and stability of the mold rack, prevents the mold rack from tipping over due to uneven stress, and enhances safety.
Smart Images

Figure CN224428360U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of mold rack equipment technology, and in particular to a mold rack for casting processing. Background Technology
[0002] Castings are metal shaped objects obtained by various casting methods. They are objects with a certain shape, size and properties obtained by pouring, injecting, sucking or other casting methods into a pre-prepared mold after smelting liquid metal, cooling and then grinding and other subsequent processing methods.
[0003] Patent document with announcement number (CN222592044U) discloses a mold rack for casting processing, including a mold rack body. The mold rack body is composed of a horizontal plate and a vertical plate. The upper and lower ends of the horizontal plate of the mold rack body are respectively movably connected to a movable storage plate and a fixed storage plate. The lower surface of the movable storage plate is rotatably connected to a roller, and the roller is slidably connected to the horizontal plate of the mold rack body. By pulling the movable storage plate, the movable storage plate can be moved from the mold rack body to a movable extension plate. With the help of a motor and a lead screw, the movable extension plate carries the movable storage plate on it and moves downward along the column, so that the height of the movable storage plate located at the highest layer of the mold rack body is reduced, so as to facilitate the retrieval or placement of casting molds from the movable storage plate.
[0004] When using the above technology, the following technical problems were found in the existing technology: the existing mold rack is not convenient for picking up and putting down the mold on the inside during use, and it is prone to deformation due to insufficient structural strength, and may even overturn when picking up and putting down the mold, which poses a safety hazard. Therefore, a mold rack for casting processing is designed to provide another technical solution to the above technical problems. Utility Model Content
[0005] Therefore, it is necessary to provide a mold holder for casting processing to address the above-mentioned technical problems, thereby solving the technical problem that it is inconvenient to lift the casting mold from the mold holder, which may cause deformation due to insufficient structural strength, and in severe cases, overturning.
[0006] To solve the above-mentioned technical problems, the present invention adopts the following technical solution:
[0007] A mold holder for casting processing includes a base and further includes:
[0008] Multiple placement compartments are stacked together vertically and each consists of a support mechanism arranged horizontally and two sets of side plates arranged vertically.
[0009] The supporting mechanism includes a set of first guide members partially fixed to the two sets of side plates, a plate slidably connected between the set of first guide members, and a first linear module fixed between the two sets of side plates and capable of moving the plate from a first position to a second position on the first guide members; and
[0010] A support mechanism that, after movement, forms a diagonal bracing angle between the base and part of the placement grid.
[0011] As a preferred embodiment of the casting processing mold frame provided by this utility model, the support mechanism includes a set of support rods whose top ends are connected to the side plate of the top placement grid via a connector, a second guide member rotatably connected to the bottom end of the set of support rods, and a second linear module fixed on the base and capable of driving the bottom end of the support rod to rotate on the second guide member, and driving the top end of the support rod to slide and rotate on the connector to form an inclined support angle.
[0012] In a preferred embodiment of the casting mold holder provided by this utility model, the connecting member includes an adapter fixed to the side plate and a sliding sleeve connected to the adapter and sleeved on the support rod.
[0013] As a preferred embodiment of the mold frame for casting processing provided by this utility model, the first guide and the second guide both consist of a fixed rail and a moving rail sleeved outside the fixed rail and which can only slide along the length direction of the fixed rail.
[0014] The flat plate is placed inside the fixed rail of the first guide member by sliding shafts fixed on both sides, and the side plates are all fixed to the fixed rail;
[0015] The guide rail of the second guide is fixed to the side of the base.
[0016] As a preferred embodiment of the casting processing mold frame provided by this utility model, the first linear module and the second linear module are both composed of a base, a transmission component fixed on the base, a set of sliding components, and a slide block that can move on the set of sliding components through the transmission component.
[0017] The first linear module is fixed at the bottom of the flat plate by multiple limiting plates, and the slide of the first linear module is fixedly connected to the flat plate by a first connecting plate. The first connecting plate is then fixed to the moving rail of the first guide member by a set of second connecting plates that bypass the side plate.
[0018] In a preferred embodiment of the casting mold holder provided by this utility model, the second linear module is inverted and fixed on the base relative to the first linear module, and the slide of the second linear module is fixedly connected to the moving rail of the second guide member through the third connecting plate.
[0019] It is clear without a doubt that the technical solution described above in this application can solve the technical problem that this application aims to address.
[0020] At the same time, through the above technical solutions, this utility model has at least the following beneficial effects:
[0021] This utility model provides a mold rack for casting processing. Through the placement mechanism, the casting mold part located on the plate can be moved out of the placement space, thereby facilitating the lifting and placement of castings on the plate. In addition, the set guide can guide the plate and prevent the plate from shifting during the movement, ensuring the stability of the casting mold during movement and improving the ease of use of the mold rack.
[0022] This utility model provides a mold frame for casting processing. Through a support mechanism, when the center of gravity of the mold frame shifts due to the removal of the casting mold part, it moves to form an inclined brace angle to provide stable support for the mold frame, preventing the mold frame from overturning due to uneven force, and improving the stability and safety of the mold frame during use. Attached Figure Description
[0023] To more clearly illustrate the technical solutions of the embodiments of this utility model, the drawings used in the description of the embodiments will be briefly introduced below. Obviously, the drawings described below are some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0024] Figure 1 This is a schematic diagram of the overall structure of a mold frame for casting processing according to the present invention;
[0025] Figure 2 This is a schematic diagram of the structure of a single placement compartment of a mold rack for casting processing according to the present invention;
[0026] Figure 3 This is a schematic diagram of the exploded disassembly of the placement grid of a mold rack for casting processing according to this utility model;
[0027] Figure 4 This is a schematic diagram of the structure of the first linear module of a mold holder for casting processing according to this utility model;
[0028] Figure 5 This is a schematic diagram of the support mechanism of a mold frame for casting processing according to the present invention.
[0029] In the diagram: 100, base; 200, placement grid; 300, bearing mechanism; 400, side plate; 500, first guide component; 510, fixed rail; 520, moving rail; 600, flat plate; 700, first linear module; 710, base; 720, transmission component; 730, sliding component; 740, slide block; 750, limiting plate; 760, first connecting plate; 770, second connecting plate; 780, third connecting plate; 800, support mechanism; 810, connecting component; 811, adapter seat; 812, sliding sleeve; 811, adapter seat; 812, sliding sleeve; 820, support rod; 830, second guide component; 840, second linear module. Detailed Implementation
[0030] To make the objectives, technical solutions, and advantages of this utility model clearer, the present utility model will be further described in detail below with reference to the accompanying drawings and embodiments. It should be understood that the specific embodiments described herein are merely illustrative of the present utility model and are not intended to limit the present utility model.
[0031] To enable those skilled in the art to better understand the present invention, the technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings.
[0032] It should be noted that, unless otherwise specified, the embodiments and features and technical solutions in the present invention can be combined with each other.
[0033] It should be noted that similar labels and letters in the following figures indicate similar items. Therefore, once an item is defined in one figure, it does not need to be further defined and explained in subsequent figures.
[0034] like Figure 1 As shown, this type of mold rack for casting processing includes a base 100, multiple storage compartments 200, and a support mechanism 800. The multiple storage compartments 200 are stacked and fixed on the base 100 in a vertical direction, and include, but are not limited to, four rows and two columns. Each storage compartment 200 is used to store a single casting mold. Each storage compartment 200 is of moderate size, capable of accommodating casting molds of different specifications while effectively preventing collisions or damage to the casting molds during storage. Furthermore, the stacked design not only saves floor space but also facilitates mold management and retrieval.
[0035] The support mechanism 800 is located between the base 100 and part of the placement grid 200 to enhance the structural stability of the mold frame and ensure the stability of the placement grid 200 when supporting the casting mold.
[0036] like Figure 2 As shown, and for reference Figure 1Each of the multiple placement compartments 200 is further composed of a support mechanism 300 and two sets of side plates 400. Specifically, the support mechanism 300 is used to place the casting mold and is located between the two sets of side plates 400. The height of the two sets of side plates 400 is moderate, which can effectively prevent the casting mold from falling from the placement compartment 200 without hindering the operator's operation of picking up and placing the casting mold. In addition, the support mechanism 300 can be partially moved out between the two sets of side plates 400, so that the casting mold on the support mechanism 300 is not blocked by the upper placement compartment 200, so that the casting mold on the support mechanism 300 can be lifted from the vertical direction, thereby further facilitating the operator's operation of picking up and placing the casting mold.
[0037] The supporting mechanism 300 further includes a set of first guide members 500, a plate 600, and a first linear module 700. Specifically, the first guide member 500 slides with the plate 600 while slidingly connecting the side plate 400, and limits the height position of the plate 600 on the first guide member 500, so that the plate 600 can slide stably on the first guide member 500 under the drive of the first linear module 700. That is, the plate 600 can move from the first position to the second position or move back to its original position in the opposite direction. In the first position, the plate 600 is located between the two sets of side plates 400 and is used to support the casting mold. In the second position, the plate 600 is partially moved out of the space between the two sets of side plates 400. At this time, the casting mold is not blocked by the upper placement grid 200, so that it can be lifted from the vertical direction.
[0038] like Figure 3 As shown, and for reference Figure 2 Each set of first guide members 500 further includes a fixed rail 510 and a moving rail 520. Specifically, the fixed rail 510 is fixed between a set of side plates 400 in the vertical direction, while the moving rail 520 is slidably connected to the outside of the fixed rail 510. The flat plate 600 is slidably connected to the fixed rail 510 through sliding shafts fixed on both sides, so that the flat plate 600 can slide stably on the moving rail 520. The moving rail 520 moves synchronously with the flat plate 600 as it moves. When the flat plate 600 moves out of the fixed rail 510, it will enter the moving rail 520 to extend the moving path of the flat plate 600 and continue to provide stable sliding support for the flat plate 600. When the flat plate 600 is almost completely displaced into the moving rail 520, the casting mold on the flat plate 600 is away from the two sets of side plates 400. At this time, there are no other bearing mechanisms 300 above the casting mold, which facilitates lifting and handling.
[0039] like Figure 4 As shown, and for reference Figure 3The first linear module 700 is further composed of a base 710, a transmission component 720, a sliding component 730, and a slide block 740. Specifically, the transmission component 720 is a lead screw, and the slide block 740 is threadedly connected to the lead screw. By driving the lead screw to rotate through a motor, the slide block 740 can be driven to move stably on the sliding component 730, which is composed of a guide rail and a slider.
[0040] Based on the above, the first linear module 700 is fixed at the bottom of the flat plate 600 by multiple limiting plates 750, and the slide 740 of the first linear module 700 is fixedly connected to the flat plate 600 by the first connecting plate 760. The first connecting plate 760 is then fixed to the moving rail 520 of the first guide member 500 by a set of second connecting plates 770 that bypass the side plate 400. Thus, the movement of the slide 740 will drive the flat plate 600 to move. That is, while the slide 740 moves, the first connecting plate 760 and the second connecting plate 770 move accordingly. The second connecting plate 770 drives the moving rail 520 to slide along the fixed rail 510, so that the flat plate 600 remains stable during the movement. At the same time, the moving rail 520 moves with the movement of the flat plate 600, which further increases the stability of the flat plate 600 during movement and increases the movement path of the flat plate 600, making it easier to move the casting mold to a suitable position and facilitate subsequent lifting and handling operations. In addition, the setup of the first linear module 700 makes the movement of the flat plate 600 more automated, reducing the tediousness of manual operation and improving work efficiency.
[0041] like Figure 5 As shown, and for reference Figure 4 The support mechanism 800 further includes a set of connectors 810, a set of struts 820, a second guide 830, and a second linear module 840. Specifically, the connectors 810 are fixed to the side plate 400 located in the top placement grid 200. The top end of the strut 820 is connected to the connectors 810 via a rotating joint, allowing the top end of the strut 820 to slide and rotate on the connectors 810, forming a diagonal bracing structure. The second guide 830 is rotatably connected to the bottom end of the strut 820, providing a rotational support point for the bottom end of the strut 820. The second linear module 840 is fixed to the base 100 and connected to the bottom end of the strut 820 via the second guide 830, enabling the bottom end of the strut 820 to rotate on the second guide 830, thereby changing the diagonal bracing angle of the strut 820.
[0042] When the second linear module 840 drives the second guide member 830 to move, the bottom end of the support rod 820 rotates on the second guide member 830, and the top end of the support rod 820 slides and rotates on the connector 810 to form an inclined bracing angle, thereby providing stable support for the placement grid 200, enhancing the overall stability of the mold frame, and preventing overturning when the bearing mechanism 300 moves the casting mold out of the side plate 400 and causes the center of gravity to deviate.
[0043] It should be noted that the second guide member 830 and the first guide member 500, as well as the second linear module 840 and the first linear module 700, have the same structure. For a detailed structural description, please refer to the above. The difference is that the fixed rail 510 of the second guide member 830 is fixed on the side of the base 100; the second linear module 840 is fixed upside down on the base 100 relative to the first linear module 700, and the slide 740 of the second linear module 840 is fixedly connected to the moving rail 520 of the second guide member 830 through the third connecting plate 780. Thus, the movement of the moving rail 520 drives the bottom end of the support rod 820 and makes it rotate and tilt under the action of the connecting member 810.
[0044] The connector 810 includes an adapter 811 fixed to the side plate 400, and a sliding sleeve 812 connected to the adapter 811 and sleeved on the support rod 820.
[0045] The connector 810 further includes an adapter 811 and a sliding sleeve 812; specifically, the adapter 811 is securely mounted on the side plate 400 by bolts or other fasteners to ensure the overall stability of the connector 810. The sliding sleeve 812 is a structure that can slide smoothly along the support rod 820. Thus, when the support rod 820 needs to adjust its tilt angle due to the movement of the moving rail 520, the sliding sleeve 812 can flexibly adapt to this change, maintain a tight fit with the support rod 820, and support the support rod 820 to form an inclined bracing angle; when the bearing mechanism 300 is in operation... Figure 1 When the casting mold is not removed from its continuous storage state, the support rod 820 can be reset to its original position under the action of the second linear module 840. Figure 1 The vertically close arrangement is designed to reduce the floor space required.
[0046] The preferred embodiments of this utility model disclosed above are merely illustrative of the present utility model. These preferred embodiments do not exhaustively describe all details, nor do they limit the present utility model to the specific implementations described. Clearly, many modifications and variations can be made based on the content of this specification. This specification selects and specifically describes these embodiments to better explain the principles and practical applications of the present utility model, thereby enabling those skilled in the art to better understand and utilize it. The present utility model is limited only by the claims and their full scope and equivalents.
Claims
1. A mold holder for casting processing, comprising a base (100), characterized in that, Also includes: Multiple placement compartments (200) are stacked together in the vertical direction and each consists of a support mechanism (300) arranged in the horizontal direction and two sets of side plates (400) arranged in the vertical direction. The supporting mechanism (300) includes a set of first guide members (500) partially fixed to the two sets of side plates (400), a plate (600) slidably connected between the set of first guide members (500), and a first linear module (700) fixed between the two sets of side plates (400) and capable of driving the plate (600) to move from a first position to a second position of the first guide member (500). as well as A support mechanism (800) is connected between the base (100) and a portion of the placement grid (200) to form a diagonal bracing angle after movement.
2. The mold holder for casting processing according to claim 1, characterized in that, The support mechanism (800) includes a set of support rods (820) whose top ends are connected to the side plate (400) of the top placement grid (200) via a connector (810), a second guide (830) rotatably connected to the bottom end of the set of support rods (820), and a second linear module (840) fixed on the base (100) and capable of driving the bottom end of the support rods (820) to rotate on the second guide (830), and driving the top end of the support rods (820) to slide and rotate on the connector (810) to form an inclined support angle.
3. The mold holder for casting processing according to claim 2, characterized in that, The connector (810) includes an adapter (811) fixed to the side plate (400) and a sliding sleeve (812) connected to the adapter (811) and sleeved on the support rod (820).
4. The mold holder for casting processing according to claim 2, characterized in that, The first guide (500) and the second guide (830) are both composed of a fixed rail (510) and a movable rail (520) sleeved on the fixed rail (510) and can only slide along the length direction of the fixed rail (510). The flat plate (600) is placed in the fixed rail (510) of the first guide member (500) by sliding shafts fixed on both sides, and the side plates (400) are all fixed to the fixed rail (510); The guide rail (510) of the second guide (830) is fixed to the side of the base (100).
5. The mold holder for casting processing according to claim 4, characterized in that, The first linear module (700) and the second linear module (840) are both composed of a base (710), a transmission component (720) fixed on the base (710), a set of sliding components (730), and a slide (740) that can move on the set of sliding components (730) via the transmission component (720); The first linear module (700) is fixed at the bottom of the flat plate (600) by multiple limiting plates (750), and the slide (740) of the first linear module (700) is fixedly connected to the flat plate (600) by a first connecting plate (760). The first connecting plate (760) is then fixed to the moving rail (520) of the first guide member (500) by a set of second connecting plates (770) that bypass the side plate (400).
6. The mold holder for casting processing according to claim 5, characterized in that, The second linear module (840) is inverted and fixed on the base (100) relative to the first linear module (700), and the slide (740) of the second linear module (840) is fixedly connected to the moving rail (520) of the second guide (830) through the third connecting plate (780).