A beverage detection experiment table

By adopting an anti-corrosion coating and cooling layer design on the beverage testing laboratory bench, the problems of easy corrosion and high-temperature damage of existing laboratory benches have been solved, achieving efficient and durable beverage testing and production control.

CN224332202UActive Publication Date: 2026-06-09GUANGDONG XIANJIN HEALTH BEVERAGE FOOD CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
GUANGDONG XIANJIN HEALTH BEVERAGE FOOD CO LTD
Filing Date
2025-05-08
Publication Date
2026-06-09

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Abstract

This utility model discloses a beverage testing experimental platform, including a first workbench, a second workbench, a storage platform, a liquid storage tank, a cooling layer, a testing layer, and a grounding base. The storage platform, the first workbench, and the second workbench are arranged opposite each other within the liquid storage tank, forming two "U"-shaped liquid flow channels. The first and second workbench are trapezoidal blocks, with their inclined surfaces facing upwards towards the liquid storage tank. The advantages of this utility model are: compared with the prior art, the outer surfaces of the workbench, storage platform, and liquid storage tank are coated with an anti-corrosion coating, which can effectively resist the corrosion of acidic and alkaline beverage residues, ensuring the long-term stability and reliability of the equipment. By equipping it with a cooling layer, the temperature of the liquid and the experimental platform can be effectively reduced when testing high-temperature liquids, preventing damage to the workbench surface and the liquid storage tank from high temperatures, and extending the service life of the equipment.
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Description

Technical Field

[0001] This utility model relates to the field of laboratory bench technology, and in particular to a beverage testing laboratory bench. Background Technology

[0002] A laboratory bench is a work platform used in a laboratory to support, operate, and place experimental equipment, instruments, and samples. Its main function is to provide convenience for researchers, ensuring sufficient space and stable support to facilitate various experimental operations.

[0003] However, most existing experimental platforms used for detecting beverage properties are ordinary flat platforms made of stainless steel with a waste liquid collection frame. Although they have a certain degree of support and strength, their work surfaces are prone to liquid accumulation, rusting and corrosion over long-term use, and damage in high-temperature environments. These types of experimental platforms only provide support and waste liquid collection functions, lacking sufficient durability and high-standard performance requirements, and thus failing to meet the application standards for testing cold and hot beverages. Summary of the Invention

[0004] (a) Problems to be solved

[0005] The technical problem to be solved by this utility model is to provide a beverage testing experimental platform in light of the current state of the technology.

[0006] (II) Technical Solution

[0007] This utility model is achieved through the following technical solution:

[0008] A beverage testing laboratory bench includes a first workbench, a second workbench, a storage platform, a liquid storage tank, a cooling layer, a testing layer, and a grounding base. The storage platform, the first workbench, and the second workbench are arranged opposite each other within the liquid storage tank, forming two "U"-shaped liquid flow channels. The first and second workbench are trapezoidal blocks, with their inclined surfaces facing upwards from the liquid storage tank.

[0009] By adopting the above technical solution, during beverage testing, the beverage liquid flows into the liquid flow tank along the inclined surface of the workbench. Tools can then be retrieved from the storage tank to test the sealing and impact resistance of the beverage bottles. Because the outer surfaces of the workbench, storage tank, and liquid storage tank are coated with an anti-corrosion coating, acidic or alkaline beverage residues will not remain on the surface, making the workbench less susceptible to damage and providing excellent corrosion resistance and stability. Furthermore, if the coating is damaged or dust or stains adhere to the workbench surface, it can be repaired and cleaned using a sprayer. For testing high-temperature liquids, the cooling layer helps to lower the temperature to prevent damage to the workbench and liquid storage tank. The experimental platform has two workbenches, left and right, which not only allow for the simultaneous testing of parameters for two beverages, improving work efficiency, but also facilitate the comparison of differences between standard and control beverages. Within the testing layer, the built-in beverage parameter comparison software displays the component differences and acceptable deviations of the two groups of beverages on the screen, thereby helping users optimize production line adjustments.

[0010] Furthermore, the beverage testing bench also includes fastening blocks. The liquid storage tank, cooling layer, testing layer, and grounding base are arranged sequentially from top to bottom and are detachably connected by fastening blocks.

[0011] Furthermore, the surface of the stage has multiple storage slots for placing experimental samples and tools. The liquid storage tank has outlets at both ends, each connected to one of two liquid flow channels, and connecting pipes are installed at the outlets. A spray nozzle is installed on the outside of the liquid storage tank, used to spray water or coating colloid onto the first worktable, second worktable, stage, and liquid storage tank. The spray nozzle includes a liquid container and a sprayer. A heat sink is installed at the bottom of the liquid storage tank.

[0012] Furthermore, the cooling layer includes a cooling tank and cooling pipes. The cooling tank has a coolant inlet and a coolant outlet at both ends, which are connected to the coolant pipes. A coolant flow channel is formed between the coolant inlet and the coolant outlet.

[0013] Furthermore, the detection layer includes a detection tank, an inlet pipe, a waste pipe, a motor, a movable plate, a detection box, and a detector. The detection tank has inlets at the top of both sides and waste holes at the bottom. The inlets are connected to the inlet pipe, and the waste holes are connected to the waste pipe. The detection box has a detection section extending through the upper and lower surfaces, and a detection element is installed within the detection section. The detection box is fixed inside the detection tank and is lower than the inlet and higher than the waste hole. A partition block is formed in the detection box, avoiding the inlet and waste hole, and its upper surface is flush with the top of the detection tank. A motor is fixedly installed between the partition block and the detection tank, and the motor is connected to the movable plate, driving the movable plate to move up and down. The movable plate is located below the detection box and its thickness is smaller than the diameter of the waste hole. The size of the hollow section inside the cross-section of the movable plate is the same as that of the detection tank. When the movable plate is not in contact with the lower end of the detection box or the bottom surface of the detection tank, the interior of the detection tank is separated by the movable plate. When the detection box is in contact with the movable plate, liquid cannot pass through the detection box.

[0014] Furthermore, the external part of the detection box is equipped with a display screen and a power control box.

[0015] Furthermore, the grounding base includes a cabinet, a waste liquid tank, and a sealed door. The waste liquid tank is connected to a waste liquid inlet on one side of the cabinet. The cabinet interior is equipped with partitions for storing objects.

[0016] Furthermore, the beverage testing bench also includes electric cylinders and a top support plate. The electric cylinders are installed at the four corners of the upper surface of the cabinet and are connected to the top support plate. The electric cylinders are used to drive the lifting plate to move up or down.

[0017] Furthermore, casters are installed at the bottom of the cabinet.

[0018] (III) Beneficial Effects

[0019] Compared with existing technologies, this utility model incorporates multiple structural designs, significantly improving testing efficiency and durability. The inner and outer surfaces of the experimental platform components are coated with an anti-corrosion coating, effectively resisting corrosion from acidic or alkaline beverage residues and ensuring the long-term stability and reliability of the equipment. If the coating is damaged or dust and stains adhere to the platform, users can easily repair and clean it using a sprayer, maintaining the equipment in optimal condition. Simultaneously, the experimental platform is equipped with a cooling layer, which effectively reduces the liquid temperature when testing high-temperature liquids, preventing damage to the work surface and liquid storage tank from high temperatures and extending the equipment's service life.

[0020] The dual workbench setup allows for simultaneous testing of parameters for two beverages, improving experimental efficiency. It also enables comparison between standard and control beverages, helping users precisely adjust production parameters. Built-in beverage parameter comparison software analyzes the differences in component composition and acceptable deviations between the two groups of beverages in real time via a display screen, assisting in production adjustments and achieving precise production control and quality management. Furthermore, the workbench is equipped with various detectors, such as a saccharimeter, pH meter, dissolved oxygen meter, and alcohol concentration meter, comprehensively covering important parameters in beverages such as sugar content, pH, dissolved oxygen, alcohol content, and metal content, ensuring that each batch of beverages meets quality standards. The workbench height is adjustable, allowing users to adjust it to the optimal working position as needed. The bottom is equipped with casters for easy movement within the laboratory, significantly improving operational convenience. Attached Figure Description

[0021] The accompanying drawings, which form part of this application, are used to provide a further understanding of the present invention. The illustrative embodiments of the present invention and their descriptions are used to explain the present invention and do not constitute an improper limitation of the present invention.

[0022] Figure 1 This is a three-dimensional schematic diagram of the beverage testing experimental platform described in this utility model;

[0023] Figure 2 This is a partial structural schematic diagram of the beverage testing experimental platform described in this utility model;

[0024] Figure 3 This is an exploded view of the cooling layer in the beverage testing experimental platform described in this utility model;

[0025] Figure 4 This is a perspective view of the detection layer in the beverage testing experimental platform described in this utility model;

[0026] Figure 5 This is an exploded view of the detection layer in the beverage testing experimental platform described in this utility model;

[0027] Figure 6 This is an exploded view of the grounding base in the beverage testing experimental platform described in this utility model;

[0028] Figure 7 This is a partial structural schematic diagram of the beverage testing experimental platform described in Embodiment 2 of this utility model;

[0029] Figure 8 This is a partial structural schematic diagram of the beverage testing experimental platform described in Embodiment 3 of this utility model.

[0030] The accompanying reference numerals are as follows:

[0031] 100. First workbench; 110. Second workbench; 120. Storage platform; 121. Storage trough; 130. Liquid storage tank; 131. Liquid flow trough; 132. Liquid outlet; 133. Connecting pipe; 134. Spraying component; 135. Liquid container; 136. Sprayer; 140. Heat sink; 200. Cooling layer; 210. Cooling tank; 220. Cooling pipe; 240. Coolant inlet; 250. Coolant outlet; 260. Coolant flow trough; 300. Detection layer; 310. Detection tank; 320. Liquid inlet pipe; 330. Waste liquid pipe; 340. Motor; 350. Movable plate; 360. Detection box; 361. Detection section; 370. Detector; 380. Liquid inlet; 390. Waste liquid hole; 391. Partition block; 392. Display screen; 393. Control box; 400. Grounding base; 410. Cabinet; 411. Partition; 420. Waste liquid tank; 421. Waste liquid inlet; 430. Sealing door; 440. Electric cylinder; 450. Top support plate; 460. Casters; 500. Fastening block. Detailed Implementation

[0032] 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.

[0033] In the description of this application, it should be understood that the terms "thickness", "upper", "lower", "front", "rear", "vertical", "horizontal", "top", "bottom", "inner", "outer", etc., indicate the orientation or positional relationship based on the orientation or positional relationship shown in the accompanying drawings. They are only for the convenience of describing this application and simplifying the description, and do not indicate or imply that the device or element referred to must have a specific orientation, or be constructed and operated in a specific orientation. Therefore, they should not be construed as limitations on this application.

[0034] Example 1

[0035] Please see Figures 1-2This embodiment provides a beverage testing experimental platform, including a first workbench, a second workbench, a storage platform, a liquid storage tank, a cooling layer, a testing layer, and a grounding base. The storage platform, the first workbench, and the second workbench are arranged opposite each other within the liquid storage tank, forming two "U"-shaped liquid flow channels. The first and second workbench are trapezoidal blocks, with their inclined surfaces facing upwards towards the liquid storage tank. The beverage testing experimental platform also includes fastening blocks. The liquid storage tank, cooling layer, testing layer, and grounding base are arranged sequentially from top to bottom and are detachably connected by the fastening blocks. The surface of the storage platform has multiple storage slots for placing experimental samples and tools. The liquid storage tank has outlets at both ends, which are connected to the two liquid flow channels respectively, and the outlets are equipped with connecting pipes. A spraying component is installed on the outside of the liquid storage tank, which is used to spray water or coating colloid onto the first workbench, the second workbench, the storage platform, and the liquid storage tank. The spraying component includes a liquid container and a sprayer. A heat dissipation block is installed at the bottom of the liquid storage tank. During beverage testing, the liquid flows along the sloping surface of the workbench into the liquid flow tank. Tools can then be retrieved from the storage tank to test the bottle's seal and impact resistance. The workbench, storage tank, and liquid storage tank are coated with an anti-corrosion coating, preventing acidic or alkaline beverage residue from remaining on the surface, thus protecting the workbench from damage and providing excellent corrosion resistance and stability. Furthermore, if the coating is damaged or dust or stains adhere to the workbench surface, it can be repaired and cleaned using a sprayer. For testing high-temperature liquids, a cooling layer helps lower the temperature to prevent damage to the workbench and liquid storage tank. The testing platform has two workbenches, allowing for simultaneous testing of parameters for two beverages, improving work efficiency, and also facilitating comparison of differences between standard and control beverages. Within the testing layer, built-in beverage parameter comparison software displays the component differences and acceptable deviations of the two analyzed beverages on a screen, helping users optimize production line adjustments.

[0036] Specifically, such as Figure 3 As shown, the cooling layer includes a cooling tank and cooling pipes. The cooling tank has coolant inlets and outlets at both ends, which are connected to the coolant pipes. A coolant flow channel is formed between the coolant inlet and outlet. The cooling layer utilizes the flowing, low-temperature liquid to remove excess heat from the storage tank and the worktable. The cooling layer effectively enhances the high-temperature resistance of the experimental platform, extending its lifespan.

[0037] Specifically, such as Figure 4 and Figure 5As shown, the detection layer includes a detection tank, an inlet pipe, a waste pipe, a motor, a movable plate, a detection box, and a detector. The detection tank has inlets at the top of both sides and waste holes at the bottom. The inlets are connected to the inlet pipe, and the waste holes are connected to the waste pipe. The detection box has a detection section penetrating the upper and lower surfaces, and a detection element is installed within the detection section. The detection box is fixed inside the detection tank, below the inlet and above the waste hole. A partition block is formed in the detection box, avoiding the inlet and waste hole, with its upper surface flush with the top of the detection tank. A motor is fixedly installed between the partition block and the detection tank, and the motor is connected to the movable plate, driving the movable plate to move up and down. The movable plate is located below the detection box and its thickness is smaller than the diameter of the waste hole to prevent waste from flowing out. The movable plate has the same size as the hollow section of the detection tank's cross-section; when the movable plate is not in contact with the lower end of the detection box or the bottom surface of the detection tank, the interior of the detection tank is separated by the movable plate. When the detection box is in contact with the movable plate, liquid cannot pass through the detection box. An external display screen and control box are installed on the detection box to control valve switching and motor movement. When the beverage liquid flows from the flow tank to the detection layer, the movable plate and the detection box are in contact. After the liquid enters the detection section and is periodically tested, the movable plate moves down, and the tested beverage follows the movable plate out of the detection box and flows through the waste liquid pipe to the waste liquid tank. The detection section is equipped with various detectors, including a saccharimeter, pH meter, dissolved oxygen detector, alcohol concentration meter, heavy metal detector, solids dissolution detector, and colorimeter, to obtain beverage parameters such as sugar content, pH, dissolved oxygen, alcohol content, metal content, solids content, and color.

[0038] Specifically, such as Figure 6 As shown, the grounding base includes a cabinet, a waste liquid tank, and a sealed door. The waste liquid tank is connected to a waste liquid inlet on one side of the cabinet. The cabinet interior is equipped with partitions for storing items such as "standard beverages, control beverages, and beverages to be tested."

[0039] Example 2

[0040] The difference between Example 2 and Example 1 is that the experimental table has an adjustable work surface height.

[0041] Specifically, such as Figure 7 As shown, the beverage testing lab bench also includes electric cylinders and a top support plate. The electric cylinders are installed at the four corners of the upper surface of the cabinet and are connected to the top support plate. The electric cylinders are used to drive the lifting plate to rise or fall. The lifting plate drives the movement of each layer of the lab bench, keeping the work surface at a comfortable height for the user.

[0042] Example 3

[0043] The difference between Example 2 and Example 1 is that the experimental platform is easily movable.

[0044] Specifically, such as Figure 8 As shown, the bottom of the cabinet is equipped with casters, making the experimental table movable and convenient to use.

[0045] The above description of the disclosed embodiments enables those skilled in the art to make or use the present invention. Various modifications to these embodiments will be readily apparent to those skilled in the art, and the general principles defined herein may be implemented in other embodiments without departing from the spirit or scope of the present invention. Therefore, the present invention is not to be limited to the embodiments shown herein, but is to be accorded the widest scope consistent with the principles and novel features disclosed herein.

Claims

1. A beverage testing laboratory platform, characterized in that, It includes a first workbench, a second workbench, a placement platform, a liquid storage tank, a cooling layer, a detection layer, and a grounding base; the placement platform, the first workbench, and the second workbench are arranged opposite to each other in the liquid storage tank and form two "U"-shaped liquid flow channels; the first workbench and the second workbench are trapezoidal blocks with their inclined surfaces facing upwards from the liquid storage tank.

2. The beverage testing experimental platform according to claim 1, characterized in that: It also includes a fastening block; the liquid storage tank, the cooling layer, the detection layer, and the grounding base are arranged sequentially from top to bottom and are detachably connected by the fastening block.

3. The beverage testing experimental platform according to claim 1, characterized in that: The surface of the platform has multiple storage slots for placing experimental samples and tools; the liquid storage tank has outlets at both ends, which are respectively connected to the two liquid flow channels, and the outlets are equipped with connecting pipes; a spraying device is installed on the outside of the liquid storage tank, which is used to spray water or coating colloid onto the first workbench, the second workbench, the platform, and the liquid storage tank; the spraying device includes a liquid container and a sprayer; a heat dissipation block is installed at the bottom of the liquid storage tank.

4. The beverage testing laboratory table according to claim 1, characterized in that: The cooling layer includes a cooling tank and a cooling pipe. The cooling tank has a coolant inlet and a coolant outlet at both ends and is connected to the cooling pipe. A coolant flow channel is formed between the coolant inlet and the coolant outlet.

5. The beverage testing laboratory table according to claim 1, characterized in that: The detection layer includes a detection tank, an inlet pipe, a waste pipe, a motor, a movable plate, a detection box, and a detector. The detection tank has inlets at its top and waste holes at its bottom on both sides. The inlets are connected to the inlet pipe, and the waste holes are connected to the waste pipe. The detection box has a detection section penetrating its upper and lower surfaces, and a detector is installed within this section. The detection box is fixed inside the detection tank and is lower than the inlet and higher than the waste hole. A partition is formed in the detection box, avoiding the inlet and waste hole. The partition block has an upper surface flush with the top of the detection tank. A motor is fixedly installed between the partition block and the detection tank, and the motor is connected to the movable plate. The motor drives the movable plate to move up and down. The movable plate is located below the detection box, and the size of the hollow portion of the cross-section of the movable plate is the same as that of the detection tank. When the movable plate separates from the lower end of the detection box or the bottom surface of the detection tank, the interior of the detection tank is separated by the movable plate. When the detection box is in contact with the movable plate, liquid cannot pass through the detection box.

6. The beverage testing laboratory table according to claim 5, characterized in that: It also includes a display screen and a power control box; the display screen and the power control box are disposed outside the detection box.

7. The beverage testing laboratory table according to claim 1, characterized in that: The grounding base includes a cabinet, a waste liquid tank, and a sealed door; the waste liquid tank is connected to a waste liquid inlet on one side of the cabinet; the cabinet is equipped with a partition for storing objects.

8. The beverage testing laboratory table according to claim 7, characterized in that: It also includes an electric cylinder and a top support plate; the electric cylinder is installed on the upper surface of the cabinet and is connected to the top support plate; the electric cylinder is used to drive the top support plate to move up or down.

9. The beverage testing laboratory table according to claim 7, characterized in that: It also includes casters, which are installed at the bottom of the cabinet.