Continuous medicinal material extraction device

Abstract

The utility model provides a continuous medicine extraction device relates to medicine extraction technical field, including the component of carrying out waste and continuous concentration output part, the upper side of component of carrying out waste is provided with the solid -liquid separation assembly of bolt sleeve joint, just the output of solid -liquid separation assembly is provided with the pressurization drive part of sleeve joint installation, the output of pressurization drive part is provided with the continuous concentration output part of sleeve joint installation, the continuous concentration output part contains sealed pipe, concentration cabin, the utility model mainly is to utilize in the output of separation cabin setting double -valve waste mouth, because double -valve waste mouth possesses two groups's output valve block to make equipment after the screw auger output operation, make solid waste can effectively reach the effect of gathering accumulation, make waste material can in time carry out the discharge treatment to reach the effect that still can reach solid -liquid separation under the condition that equipment does not stop machine, guarantees the stable processing efficiency of equipment.

Description

Technical Field

[0001] This utility model relates to the field of medicinal material extraction technology, and in particular to a continuous medicinal material extraction device. Background Technology

[0002] The chemical composition of medicinal materials is very complex, containing a variety of effective components, ineffective components, and even toxic components. Extracting the effective components and further separating and purifying them to obtain effective monomers is an important aspect of traditional Chinese medicine research. Medicinal material extraction utilizes certain technologies to maximize the extraction of effective components, thereby improving the intrinsic quality and clinical therapeutic effects of traditional Chinese medicine preparations and maximizing the efficacy of medicinal materials.

[0003] Existing medicinal herb extraction devices, such as the one disclosed in application number CN202110909964.8, which relates to the field of traditional Chinese medicine extraction, include a decoction tank equipped with a heating element. A filter barrel is placed into the decoction tank through the discharge port. The bottom of the filter barrel has an insertion part, and the top of the filter barrel has a pressure plate. The decoction tank is equipped with a lifting component to prevent the medicinal herbs from floating and a rotating component to rotate the filter barrel to dry the dregs. The lifting component includes a lifting screw, a lifting block above the decoction tank, and an annular lifting seat inside the decoction tank. The lifting block and the annular lifting seat are both threadedly connected to the lifting screw. However, in the above technology, when cleaning is required, the equipment needs to be stopped in a timely manner, which delays the normal processing operation of the equipment. Therefore, this utility model proposes a continuous medicinal herb extraction device to solve the problems existing in the prior art. Utility Model Content

[0004] To address the aforementioned problems, this utility model proposes a continuous medicinal herb extraction device. This continuous medicinal herb extraction device mainly utilizes a double-valve waste outlet at the output end of the separation chamber. Because the double-valve waste outlet has two sets of output valve blocks, after the auger outputs the equipment, solid waste can effectively achieve the effect of accumulation and stacking, allowing the waste material to be discharged in a timely manner. This achieves solid-liquid separation even without stopping the equipment, ensuring stable processing efficiency.

[0005] To achieve the purpose of this utility model, the utility model is implemented through the following technical solution: a continuous medicinal material extraction device, including a waste discharge component and a continuous concentration output component, wherein a solid-liquid separation component is bolted to the inner side of the waste discharge component, and a pressure driving component is sleeved to the output end of the solid-liquid separation component, and a continuous concentration output component is sleeved to the output end of the pressure driving component.

[0006] The continuous concentration output component includes a sealing tube, a concentration chamber, a second outer tube, a second heating rod, an inner frame, a filter element assembly, a third node chamber, and a discharge valve block. The sealing tube is located at the output end of the pressurization drive component, and a concentration chamber is sleeved onto one end of the sealing tube. A second outer tube for mounting the second heating rod is located on the outer side of the concentration chamber. An inner frame for mounting the filter element assembly is located inside the concentration chamber. A third node chamber is located at the output end of the concentration chamber, and a discharge valve block is located at the output end of the third node chamber.

[0007] In a preferred embodiment of this utility model, multiple sets of filter elements are distributed parallel to the central axis of the inner frame, and multiple sets of concentration chambers are distributed parallel to each other.

[0008] In a preferred embodiment of this utility model, the waste disposal assembly includes a mounting base, bolt pads, side base plates, an upper base, a material conveying box, a crossbeam frame, and a mounting base plate. Bolt pads are provided above both ends of the mounting base, and a side base plate for mounting the material conveying box is provided above the bolt pads. An upper base plate for mounting the crossbeam frame is provided at the top of the side base plate, and a mounting base plate is provided above the middle of the mounting base.

[0009] In a preferred embodiment of this utility model, the solid-liquid separation assembly includes a bolt bearing, a drive motor, a back plate, a separation chamber, a spiral auger, a feed chamber, a water inlet valve, a first outer pipe, a first heating rod, and a dual-valve waste outlet. The bolt bearing is located on the outer side of the upper base, the drive motor is located on the outer side of the bolt bearing, the back plate is located on the inner side of the bolt bearing, and the separation chamber for mounting the spiral auger is located on the inner side of the back plate.

[0010] In a preferred embodiment of the present invention, a feed chamber with a water inlet valve is provided above one end of the separation chamber, a double-valve waste outlet is provided below the other end of the separation chamber, a first outer tube is provided on the outer side of the separation chamber, and a first heating rod is provided inside the first outer tube.

[0011] In a preferred embodiment of this utility model, the pressurization drive component includes a liquid outlet pipe, a directional valve, a pressurization pump, a first node chamber, and a second node chamber. The liquid outlet pipe is located at the output end of the separation chamber, the output end of the liquid outlet pipe is provided with a directional valve, the output end of the directional valve is provided with a pressurization pump, the output end of the pressurization pump is provided with a first node chamber, and the output end of the first node chamber is provided with a second node chamber.

[0012] The beneficial effects of this utility model are as follows:

[0013] This utility model mainly utilizes a dual-valve waste outlet at the output end of the separation chamber. Because the dual-valve waste outlet has two sets of output valve blocks, after the auger is running, solid waste can be effectively accumulated and piled up, allowing the waste material to be discharged in a timely manner. This achieves solid-liquid separation even without stopping the equipment, ensuring stable processing efficiency. Attached Figure Description

[0014] Figure 1 This is a three-dimensional structural diagram of the present invention;

[0015] Figure 2 This is a bottom-view three-dimensional structural diagram of the present invention;

[0016] Figure 3 This is a cross-sectional three-dimensional structural diagram of the present invention;

[0017] Figure 4 This is a three-dimensional structural diagram of the continuous concentration output component of this utility model.

[0018] The components include: 1. Waste discharge assembly; 101. Mounting base; 102. Bolt washer; 103. Side base plate; 104. Upper base; 105. Feed box; 106. Crossbeam frame; 107. Set base plate; 2. Solid-liquid separation assembly; 201. Bolt bearing; 202. Drive motor; 203. Back plate; 204. Separation chamber; 205. Spiral auger; 206. Feed chamber; 207. Water inlet valve; 208. First outer pipe; 209. 1. First heating rod; 2010. Dual-valve waste outlet; 3. Pressurization drive component; 301. Liquid outlet pipe; 302. Diverter valve; 303. Pressurization pump; 304. First node chamber; 305. Second node chamber; 4. Continuous concentration output component; 401. Sealing pipe; 402. Concentration chamber; 403. Second outer pipe; 404. Second heating rod; 405. Inner frame; 406. Filter cartridge assembly; 407. Third node chamber; 408. Discharge valve block. Detailed Implementation

[0019] To deepen the understanding of this utility model, the following detailed description will be provided in conjunction with embodiments. These embodiments are only used to explain this utility model and do not constitute a limitation on the scope of protection of this utility model.

[0020] according to Figure 1-4 As shown, this embodiment proposes a continuous medicinal material extraction device, including a waste discharge component 1 and a continuous concentration output component 4. A solid-liquid separation component 2 with bolts is provided on the inner side above the waste discharge component 1, and a pressure driving component 3 with a sleeve is provided at the output end of the solid-liquid separation component 2. The continuous concentration output component 4 with a sleeve is provided at the output end of the pressure driving component 3.

[0021] The continuous concentration output component 4 includes a sealing pipe 401, a concentration chamber 402, a second outer pipe 403, a second heating rod 404, an inner frame 405, a filter element assembly 406, a third node chamber 407, and a discharge valve block 408. The sealing pipe 401 is located at the output end of the pressurization drive component 3, and one end of the sealing pipe 401 is fitted with the concentration chamber 402. The outer side of the concentration chamber 402 is fitted with the second outer pipe 403, on which the second heating rod 404 is installed. The inner frame 405, on which the filter element assembly 406 is installed, is located inside the concentration chamber 402. The output end of the concentration chamber 402 is fitted with the third node chamber 407, and the output end of the third node chamber 407 is fitted with the discharge valve block 408.

[0022] Multiple filter cartridges are distributed in parallel along the central axis of the inner frame 405 within filter cartridge 406, and multiple concentration chambers are distributed in parallel within concentration chamber 402.

[0023] In this embodiment, the liquid raw material is then input into the concentration chamber 402 at the output end of the sealed pipe 401, and the second heating rod 404 on the second outer pipe 403 is output to achieve the heating effect. In conjunction with the inner frame 405 and the filter element group 406, the material is concentrated in advance, and finally discharged through the third node chamber 407 and the discharge valve block 408.

[0024] The waste removal assembly 1 includes a mounting base 101, bolt pads 102, side base plates 103, upper base 104, feed box 105, crossbeam frame 106, and mounting base plate 107. Bolt pads 102 are provided above both ends of the mounting base 101, and the side base plate 103 for mounting the feed box 105 is provided above the bolt pads 102. The upper base 104 for mounting the crossbeam frame 106 is provided at the top of the side base plate 103, and the mounting base plate 107 is provided above the middle part of the mounting base 101.

[0025] In this embodiment, during use, the upper side substrate 103 is bolted to the upper two ends of the mounting base 101 using bolt pads 102 so that the upper base 104 and the mounting substrate 107 can effectively assemble and combine the various components, and the material conveying box 105 can effectively output the waste material.

[0026] The solid-liquid separation assembly 2 includes a bolt bearing 201, a drive motor 202, a back plate 203, a separation chamber 204, a spiral auger 205, a feed chamber 206, a water inlet valve 207, a first outer pipe 208, a first heating rod 209, and a dual-valve waste outlet 2010. The bolt bearing 201 is located on the outer side of the upper base 104. The drive motor 202 is located on the outer side of the bolt bearing 201. The back plate 203 is located on the inner side of the bolt bearing 201, and the separation chamber 204 for mounting the spiral auger 205 is located on the inner side of the back plate 203.

[0027] In this embodiment, the drive motor 202 on the outer side of the bolt bearing 201 is used to output power to drive the output end to run, so that after the drive motor 202 outputs and runs, it drives the spiral auger 205 inside the separation chamber 204 to output and run, thereby pushing the material. The installed double valve waste outlet 2010 has two sets of valve plates, thus achieving the effect of discharging solid waste.

[0028] A feed chamber 206 with an inlet valve 207 is provided above one end of the separation chamber 204, and a double-valve waste outlet 2010 is provided below the other end of the separation chamber 204. A first outer pipe 208 is provided on the outer side of the separation chamber 204, and a first heating rod 209 is provided inside the first outer pipe 208.

[0029] In this embodiment, when processing is required, the feed chamber 206 is used in conjunction with the water inlet valve 207 to input medicinal materials and sufficient water, and the materials are input into the separation chamber 204. The first heating rod 209 inside the first outer pipe 208 is then output to achieve the effect of heating and discharging the materials.

[0030] The pressurization drive component 3 includes an outlet pipe 301, a directional valve 302, a pressurization pump 303, a first node chamber 304, and a second node chamber 305. The outlet pipe 301 is located at the output end of the separation chamber 204. The output end of the outlet pipe 301 is equipped with the directional valve 302, and the output end of the directional valve 302 is equipped with the pressurization pump 303. The output end of the pressurization pump 303 is equipped with the first node chamber 304, and the output end of the first node chamber 304 is equipped with the second node chamber 305.

[0031] In this embodiment, the outlet pipe 301 is then opened in conjunction with the directional valve 302. After opening, the pressurized liquid pump 303 outputs power to drive the output end to run, so that after the pressurized liquid pump 303 outputs and runs, the liquid raw material is input into the first node chamber 304 and the second node chamber 305 to achieve the output effect.

[0032] The working principle of this continuous medicinal herb extraction device is as follows: During use, the upper side base plate 103 is bolted to both ends of the mounting base 101 using bolt pads 102, so that the upper base 104 and the mounting base plate 107 can be effectively assembled and combined. The feed box 105 effectively outputs waste. When processing is required, the feed chamber 206, in conjunction with the water inlet valve 207, is used to input medicinal herbs and sufficient water, feeding the material into the separation chamber 204. The first heating rod 209 inside the first outer pipe 208 then outputs power to achieve the effect of heating and discharging the material. Then, the drive motor 202 on the outer side of the bolt bearing 201 outputs power to drive the output end, so that the drive motor 202 drives the spiral auger inside the separation chamber 204. After the output operation of 205 is started, the material is pushed. The installed double valve waste outlet 2010 has two sets of valve plates, so it can discharge solid waste. Then, the liquid outlet pipe 301 is opened in conjunction with the diversion valve 302. After opening, the pressurized liquid pump 303 outputs power to drive the output end to run. After the pressurized liquid pump 303 is running, the liquid raw material is input into the first node chamber 304 and the second node chamber 305 to achieve the output effect. Then, the liquid raw material is input into the concentration chamber 402 at the output end of the sealing pipe 401, and the second heating rod 404 on the second outer pipe 403 is operated to achieve the heating effect. With the help of the inner frame 405 and the filter element group 406, the material is concentrated in advance. Finally, the material is discharged through the third node chamber 407 and the discharge valve block 408.

[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. The scope of protection of this utility model is defined by the appended claims and their equivalents.

Claims

1. A continuous medicinal herb extraction device, comprising a waste discharge component (1) and a continuous concentration output component (4), characterized in that: The solid-liquid separation component (2) is bolted to the inner side of the waste discharge component (1), and the output end of the solid-liquid separation component (2) is provided with a pressurized drive component (3) installed in a sleeve, and the output end of the pressurized drive component (3) is provided with a continuous concentration output component (4) installed in a sleeve. The continuous concentration output component (4) includes a sealing tube (401), a concentration chamber (402), a second outer tube (403), a second heating rod (404), an inner frame (405), a filter element assembly (406), a third node chamber (407), and a discharge valve block (408). The sealing tube (401) is located at the output end of the pressurization drive component (3), and a concentration chamber (402) is provided at one end of the sealing tube (401). A second outer tube (403) for installing the second heating rod (404) is provided on the outer side of the concentration chamber (402). An inner frame (405) for installing the filter element assembly (406) is provided inside the concentration chamber (402). A third node chamber (407) is provided at the output end of the concentration chamber (402), and a discharge valve block (408) is provided at the output end of the third node chamber (407).

2. The continuous medicinal material extraction device according to claim 1, characterized in that: Multiple sets of filter cartridges (406) are distributed in parallel along the central axis of the inner frame (405), and multiple sets of concentration chambers (402) are distributed in parallel.

3. The continuous medicinal material extraction device according to claim 1, characterized in that: The waste disposal assembly (1) includes a mounting base (101), bolt pads (102), side base plates (103), upper base (104), material conveying box (105), crossbeam frame (106), and mounting base plate (107). Bolt pads (102) are provided above both ends of the mounting base (101), and side base plates (103) for installing material conveying box (105) are provided above the bolt pads (102). The upper base plate (104) for installing crossbeam frame (106) is provided at the top of the side base plate (103), and mounting base plate (107) is provided above the middle part of the mounting base (101).

4. The continuous medicinal material extraction device according to claim 3, characterized in that: The solid-liquid separation assembly (2) includes a bolt bearing (201), a drive motor (202), a back plate (203), a separation chamber (204), a spiral auger (205), a feed chamber (206), a water inlet valve (207), a first outer pipe (208), a first heating rod (209), and a double-valve waste outlet (2010). The bolt bearing (201) is located on the outer side of the upper base (104). The drive motor (202) is located on the outer side of the bolt bearing (201). The back plate (203) is located on the inner side of the bolt bearing (201), and the separation chamber (204) on the inner side of the back plate (203) is used to install the spiral auger (205).

5. A continuous medicinal herb extraction device according to claim 4, characterized in that: A feed chamber (206) with a water inlet valve (207) is provided above one end of the separation chamber (204), and a double-valve waste outlet (2010) is provided below the other end of the separation chamber (204). A first outer tube (208) is provided on the outer side of the separation chamber (204), and a first heating rod (209) is provided inside the first outer tube (208).

6. The continuous medicinal material extraction device according to claim 4, characterized in that: The pressurization drive component (3) includes an outlet pipe (301), a directional valve (302), a pressurization pump (303), a first node chamber (304), and a second node chamber (305). The outlet pipe (301) is located at the output end of the separation chamber (204). The output end of the outlet pipe (301) is provided with a directional valve (302), and the output end of the directional valve (302) is provided with a pressurization pump (303). The output end of the pressurization pump (303) is provided with a first node chamber (304), and the output end of the first node chamber (304) is provided with a second node chamber (305).

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