A dough cutting device for a dough sheeting machine

Abstract

This utility model relates to the field of dough cutting machines, specifically a dough cutting device for rolling out dough sheets with adjustable size. It includes a dough cutting machine body, a control unit, a drive unit fixedly connected to the top of the control unit, a material holding cylinder fixedly connected to one side of the drive unit, a push block movably connected to the inner cavity of the material holding cylinder, a cylinder cutting blade on the surface of the material holding cylinder, and an adjustment mechanism on one side of the material holding cylinder, the adjustment mechanism including a fixed shell. This utility model, through the combined use of the dough cutting machine and the adjustment mechanism, allows for adjustment of the outlet size, facilitating the cutting of dough sheets into different sizes by the cylinder cutting machine. This solves the problem that the outlet size of general dough cutting machines is fixed, making it inconvenient to adjust the size of the cut dough sheets and lacking flexibility.

Description

Technical Field

[0001] This utility model relates to the field of dough cutting machines, specifically a dough cutting device for rolling out dough sheets that is easy to adjust in size. Background Technology

[0002] A pellet cutter is a specialized device used to precisely cut pharmaceuticals, chemicals, adhesives, or other paste / semi-solid materials into fixed doses or shapes. It is widely used in the pharmaceutical, chemical, food, and electronic adhesive industries. Pellet cutters are also used in the production of dough sheets.

[0003] To cut dough pieces into appropriate sizes, a dough piece cutter is used. However, the output size of a typical dough piece cutter is fixed, making it difficult to adjust the size of the cut pieces and lacking flexibility. Utility Model Content

[0004] To address the shortcomings of existing technologies, the discharge port size of general dough cutting machines is fixed, making it inconvenient to adjust the size of the cut dough pieces and lacking flexibility. This utility model proposes a dough cutting device for rolling out dough sheets that is easy to adjust in size.

[0005] The technical solution adopted by this utility model to solve its technical problem is: a dough sheet cutting device for easy adjustment of size, including a dough sheet cutting machine body, the dough sheet cutting machine body including a control machine, a drive machine fixedly connected to the top of the control machine, a material holding cylinder fixedly connected to one side of the drive machine, a push block movably connected to the inner cavity of the material holding cylinder, a cylinder cutting blade provided on the surface of the material holding cylinder, and an adjustment mechanism provided on one side of the material holding cylinder;

[0006] The adjusting mechanism includes a fixed shell, the surface of which is fixedly connected to one side of the material container. A sliding block is movably connected to the surface of the fixed shell. There are six sliding blocks. A first sliding post and a second sliding post are fixedly connected to the surface of each sliding block. The surface of the second sliding post is movably connected to the inner cavity of the fixed shell. A rotating shell is movably connected to the surface of the fixed shell. The inner cavity of the rotating shell is movably connected to the surface of the first sliding post.

[0007] Preferably, the surface of the fixed shell is provided with a second sliding groove, and the number of the second sliding groove is six. The inner cavity of each second sliding groove is movably connected to the surface of a second sliding column.

[0008] Preferably, the surface of the rotating shell is provided with guide grooves, and the number of guide grooves is six. The inner cavity of each guide groove is movably connected to the surface of a first sliding column.

[0009] Preferably, a limiting ring is fixedly connected to the surface of each of the first sliding columns, and the surface of the limiting ring is movably connected to the inner cavity of the rotating shell.

[0010] Preferably, the surface of the fixed shell is provided with a first sliding groove, and the inner cavity of each first sliding groove is movably connected to the surface of a limiting ring.

[0011] Preferably, a limiting groove is formed on the surface of the fixed shell, and a limiting ring is movably connected to the inner cavity of the limiting groove.

[0012] Preferably, a support frame is fixedly connected to the surface of the rotating shell, and a threaded post is threadedly connected to the inner cavity of the support frame. A rotating block is fixedly connected to one end of the threaded post, and the other end of the threaded post passes through the rotating shell and the limiting ring and contacts the inner cavity of the fixed shell.

[0013] The advantages of this utility model are:

[0014] This invention uses a dough cutting machine and an adjustment mechanism in conjunction. The size of the discharge port can be adjusted by the adjustment mechanism, which facilitates the cutting of dough into different sizes by the cylinder cutting machine for the production of dough sheets of different sizes. This solves the problem that the discharge port size of ordinary dough cutting machines is fixed and does not make it convenient to adjust the size of the cut dough pieces, thus lacking flexibility. Attached Figure Description

[0015] To more clearly illustrate the technical solutions in the embodiments of this utility model or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this utility model. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.

[0016] Figure 1 This is a schematic diagram of the overall structure of this utility model;

[0017] Figure 2 This is a schematic diagram of the cross-sectional structure of the material container of this utility model;

[0018] Figure 3 This is a schematic diagram of the rotating shell structure of this utility model;

[0019] Figure 4 This is a schematic diagram of the exploded structure of the rotating shell of this utility model;

[0020] Figure 5 This is a schematic diagram of the limiting groove structure of this utility model.

[0021] In the diagram: 1. Particle cutting machine body; 101. Control unit; 102. Drive unit; 103. Push block; 104. Material container; 105. Cylinder cutting blade; 2. Adjustment mechanism; 201. Rotating shell; 202. Fixed shell; 203. Rotating block; 204. Support frame; 205. Threaded column; 206. Guide groove; 207. First sliding groove; 208. First sliding column; 209. Limiting ring; 210. Sliding block; 211. Second sliding column; 212. Second sliding groove; 213. Limiting groove; 214. Limiting ring. Detailed Implementation

[0022] 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 scope of protection of the present utility model.

[0023] The following is in conjunction with the appendix Figure 1-5 This application will be described in further detail.

[0024] This application discloses a dough sheet cutting device that allows for easy size adjustment. (See also...) Figure 1 and Figure 5 A dough sheet cutting device for easy size adjustment includes a dough sheet cutting machine body 1, a control machine 101, a drive machine 102 fixedly connected to the top of the control machine 101, a material holding cylinder 104 fixedly connected to one side of the drive machine 102, a push block 103 movably connected to the inner cavity of the material holding cylinder 104, a cylinder cutting blade 105 provided on the surface of the material holding cylinder 104, and an adjustment mechanism 2 provided on one side of the material holding cylinder 104.

[0025] The adjusting mechanism 2 includes a fixed shell 202, the surface of which is fixedly connected to one side of the material container 104. Sliding blocks 210 are movably connected to the surface of the fixed shell 202. There are six sliding blocks 210. A first sliding post 208 and a second sliding post 211 are fixedly connected to the surface of each sliding block 210. The surface of the second sliding post 211 is movably connected to the inner cavity of the fixed shell 202. A rotating shell 201 is movably connected to the surface of the fixed shell 202. The inner cavity of the rotating shell 201 is movably connected to the surface of the first sliding post 208.

[0026] Reference Figure 4The surface of the fixed shell 202 is provided with a second sliding groove 212. There are six second sliding grooves 212. The inner cavity of each second sliding groove 212 is movably connected to the surface of a second sliding column 211. The second sliding grooves 212 guide the second sliding column 211 to slide in the inner cavity of the fixed shell 202, thereby indirectly guiding the sliding block 210 to slide.

[0027] Reference Figure 4 The surface of the rotating shell 201 is provided with guide grooves 206, and there are six guide grooves 206. The inner cavity of each guide groove 206 is movably connected to the surface of a first sliding column 208. The guide grooves 206 guide the first sliding column 208 to slide in the inner cavity of the rotating shell 201. Since the guide grooves 206 are inclined, the rotating shell 201 can drive the first sliding column 208 to move when it rotates, thereby driving the sliding block 210 to move. By adjusting the contact surface of each sliding block 210, the size of the central opening exposed by all sliding blocks 210 can be adjusted.

[0028] Reference Figure 3 and Figure 4 Each first sliding post 208 has a fixedly connected limiting ring 209 on its surface. The surface of the limiting ring 209 is movably connected to the inner cavity of the rotating shell 201. The limiting ring 209 limits the sliding of the first sliding post 208 in the inner cavity of the guide groove 206. One side of the limiting ring 209 is flush with one side of the rotating shell 201, so it will not affect the cylinder cutting blade 105 from cutting the extruded material.

[0029] Reference Figure 4 The surface of the fixed shell 202 is provided with a first sliding groove 207. The inner cavity of each first sliding groove 207 is movably connected to the surface of a limiting ring 209. By setting the first sliding groove 207, the first sliding column 208 is slidably driven to slide the limiting ring 209 in the inner cavity of the rotating shell 201, which provides sliding space and prevents the limiting ring 209 from being stuck.

[0030] Reference Figure 4 and Figure 5 A limiting groove 213 is provided on the surface of the fixed shell 202. A limiting ring 214 is movably connected to the inner cavity of the limiting groove 213. The limiting groove 213 and the limiting ring 214 limit the rotating shell 201 when it slides on the surface of the fixed shell 202, preventing the rotating shell 201 from detaching from the surface of the fixed shell 202 or from shaking when the rotating shell 201 rotates.

[0031] Reference Figure 4 and Figure 5A support frame 204 is fixedly connected to the surface of the rotating shell 201. A threaded post 205 is threadedly connected to the inner cavity of the support frame 204. A rotating block 203 is fixedly connected to one end of the threaded post 205. The other end of the threaded post 205 passes through the rotating shell 201 and the limiting ring 214 and contacts the inner cavity of the fixed shell 202. By using the rotating block 203, the support frame 204 and the threaded post 205 together, the rotating block 203 can be turned to drive the threaded post 205 to rotate in the inner cavity of the support frame 204 and move threadedly into the inner cavity of the limiting groove 213 until it is in close contact with the inner cavity of the limiting groove 213. The rotating shell 201 and the fixed shell 202 are indirectly fixed by friction, thereby indirectly fixing the moved sliding block 210.

[0032] Working principle: When the dough cutting machine body 1 needs to cut dough pieces, the dough pieces are placed in the holding cylinder 104. The control machine 101 controls the drive machine 102 to start working. The drive machine 102 is equipped with a pushing device, which pushes the pushing block 103, thereby pushing and extruding the dough pieces to the other end of the holding cylinder 104. The cylinder cutting blade 105 includes a cylinder and a cutting blade. The telescopic end of the cylinder is fixedly connected to the cutting blade. The cylinder drives the cutting blade to cut off the dough pieces extruded into the inner cavity of the holding cylinder 104. The above is the prior art and will not be elaborated further. When it is necessary to adjust the size of the cut dough pieces, the support frame 204 is rotated, thereby driving the rotating shell 201 to rotate. The rotating shell 201 drives the limiting ring 214 to slide in the inner cavity of the fixed shell 202. At the same time, the rotating shell 201 drives the first The sliding column 208 slides in the inner cavity of the guide groove 206. The first sliding column 208 drives the sliding block 210 to slide, and the sliding block 210 drives the second sliding column 211 to slide in the inner cavity of the second sliding groove 212. By adjusting the size of the contact surface between each sliding block 210, the size of the central opening exposed by all sliding blocks 210 is adjusted. When the adjustment is completed, the rotating block 203 is turned, and the rotating block 203 drives the threaded column 205 to rotate in the inner cavity of the support frame 204 and make close contact with the inner cavity of the limiting groove 213. The position of the rotating shell 201 is fixed by the friction between the threaded column 205 and the inner cavity of the limiting groove 213. At this time, the dough pushed by the pushing block 103 will be squeezed out through the central opening of each sliding block 210. The squeezed dough is cut off by the cylinder cutting blade 105.

[0033] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. Those skilled in the art should understand that this utility model is not limited to the above embodiments. The embodiments and descriptions in the specification are merely illustrative of the principles of this utility model. Various changes and modifications can be made to this utility model without departing from its spirit and scope, and all such changes and modifications fall within the scope of the claimed utility model.

Claims

1. A dough sheet cutting device for easy size adjustment, comprising a dough sheet cutting machine body (1), characterized in that: The main body (1) of the pellet cutting machine includes a control unit (101), a drive unit (102) is fixedly connected to the top of the control unit (101), a material container (104) is fixedly connected to one side of the drive unit (102), a push block (103) is movably connected to the inner cavity of the material container (104), a cylinder cutting blade (105) is provided on the surface of the material container (104), and an adjustment mechanism (2) is provided on one side of the material container (104). The adjusting mechanism (2) includes a fixed shell (202), the surface of which is fixedly connected to one side of the material container (104), and a sliding block (210) is movably connected to the surface of the fixed shell (202). There are six sliding blocks (210), and a first sliding column (208) and a second sliding column (211) are fixedly connected to the surface of each sliding block (210). The surface of the second sliding column (211) is movably connected to the inner cavity of the fixed shell (202), and a rotating shell (201) is movably connected to the surface of the fixed shell (202). The inner cavity of the rotating shell (201) is movably connected to the surface of the first sliding column (208).

2. The dough sheet cutting device for easy size adjustment according to claim 1, characterized in that: The surface of the fixed shell (202) is provided with a second sliding groove (212), and there are six second sliding grooves (212). The inner cavity of each second sliding groove (212) is movably connected to the surface of a second sliding column (211).

3. The dough sheet cutting device for easy size adjustment according to claim 1, characterized in that: The rotating shell (201) has guide grooves (206) on its surface. There are six guide grooves (206), and the inner cavity of each guide groove (206) is movably connected to the surface of a first sliding column (208).

4. The dough sheet cutting device for easy size adjustment according to claim 1, characterized in that: Each of the first sliding columns (208) has a limiting ring (209) fixedly connected to its surface, and the surface of the limiting ring (209) is movably connected to the inner cavity of the rotating shell (201).

5. The dough sheet cutting device for easy size adjustment according to claim 1, characterized in that: The surface of the fixed shell (202) is provided with a first sliding groove (207), and the inner cavity of each first sliding groove (207) is movably connected to the surface of a limiting ring (209).

6. The dough sheet cutting device for easy size adjustment according to claim 1, characterized in that: The surface of the fixed shell (202) is provided with a limiting groove (213), and the inner cavity of the limiting groove (213) is movably connected to a limiting ring (214).

7. The dough sheet cutting device for easy size adjustment according to claim 1, characterized in that: A support frame (204) is fixedly connected to the surface of the rotating shell (201). A threaded post (205) is threadedly connected to the inner cavity of the support frame (204). A rotating block (203) is fixedly connected to one end of the threaded post (205). The other end of the threaded post (205) passes through the rotating shell (201) and the limiting ring (214) and contacts the inner cavity of the fixed shell (202).

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