Multi-dimensional adjustable workshop data acquisition device

By using a multi-dimensional adjustable workshop data acquisition device, which utilizes installation components and angle adjustment components to achieve flexible installation and angle adjustment of the equipment, the problem of the inability to adjust the angle after the equipment is fixed in the existing technology is solved, thereby improving the accuracy of data acquisition and production efficiency.

CN224434091UActive Publication Date: 2026-06-30SIPPR ENG GROUP +1

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
SIPPR ENG GROUP
Filing Date
2025-09-12
Publication Date
2026-06-30

AI Technical Summary

Technical Problem

The existing workshop data acquisition equipment cannot be adjusted after it is fixed, which makes it impossible to collect data accurately when the layout of production equipment changes, and the inconvenience of disassembly affects production efficiency.

Method used

A multi-dimensional adjustable workshop data acquisition device is adopted, including installation components, fixing components and angle adjustment components. The device can be flexibly installed and its angle can be adjusted through vacuum adsorption and magnetic connection. The position and angle can be flexibly adjusted by combining the adjusting screw and the cross shaft.

Benefits of technology

It enables flexible installation and angle adjustment of data acquisition equipment, meeting the needs of different installation environments and improving the accuracy of data acquisition and production efficiency.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model discloses a multi-dimensional adjustable workshop data acquisition device, including a mounting component, a first fixing component, a second fixing component, and an angle adjustment component. The mounting component includes an outer protective sleeve, an adjusting sleeve, and an adjusting screw. The adjusting sleeve is located inside the outer protective sleeve and has a clearance fit with it. One end of the adjusting sleeve extends outward from the outer protective sleeve. The adjusting sleeve is connected to the second fixing component through the angle adjustment component. The adjusting screw is threadedly connected to the adjusting sleeve. The first fixing component includes a mounting base, a double-ended screw, and a pair of spaced-apart clamps. The two threaded sections of the double-ended screw have opposite directions of rotation. This utility model is fixed to a fixed foundation in the workshop by the first fixing component, making installation simple and convenient. The position of the data acquisition device body on the second fixing component is flexibly adjustable, and the length of the mounting component is also flexibly adjustable. The data acquisition device body is connected to the mounting component through the angle adjustment component, enabling flexible adjustment of the position and angle of the data acquisition device body.
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Description

Technical Field

[0001] This utility model relates to the field of workshop data acquisition, and in particular to a multi-dimensional adjustable workshop data acquisition device. Background Technology

[0002] In modern industrial production, data acquisition equipment is an essential piece of equipment in the production workshop, affecting production management, quality control, and equipment maintenance. Currently, workshop data acquisition equipment is mainly installed in a fixed manner. Once fixed, the angle cannot be adjusted, making it difficult to collect the required data accurately when the layout of production equipment changes. In addition, when replacement is needed or a malfunction occurs, the entire equipment needs to be disassembled from the workshop frame, which is inconvenient, inefficient, and impacts production efficiency. Summary of the Invention

[0003] In view of this, this utility model proposes a multi-dimensional adjustable workshop data acquisition device, which can realize flexible installation and disassembly of the data acquisition device body, and is conducive to flexible adjustment of the angle.

[0004] To achieve the above objectives, the present invention adopts the following technical solution:

[0005] The multi-dimensional adjustable workshop data acquisition device of this utility model includes a data acquisition device body and an installation structure. The installation structure includes an installation component, at least two first fixing components fixed on a fixed foundation in the workshop, a second fixing component for fixing the data acquisition device body, and an angle adjustment component for adjusting the angle of the data acquisition device body.

[0006] The mounting assembly is a long rod structure, which includes an outer protective sleeve, an adjusting sleeve with internal threads, and an adjusting screw. One end of the adjusting screw is connected to the outer protective sleeve through a bearing. The adjusting sleeve is located inside the outer protective sleeve and is clearance-fitted with the outer protective sleeve. One end of the adjusting sleeve extends outward from the outer protective sleeve. The extended end of the adjusting sleeve is connected to the second fixing assembly through the angle adjusting assembly. The adjusting screw is threadedly connected to the adjusting sleeve.

[0007] At least two identical first fixing components are spaced apart on the outer casing. Each component includes a mounting base, a double-ended screw, and a pair of spaced clamps. The mounting base is fixed to the mounting component and has an axially opened mounting hole. The double-ended screw is rotatably disposed in the mounting hole via a bearing. The two threaded sections of the double-ended screw have opposite directions of rotation, and each threaded section is screwed with one of the clamps.

[0008] The beneficial effects are: This utility model is fixed on the fixed foundation in the workshop by the first fixing component, which makes the installation simple and convenient; the position of the data acquisition device body on the second fixing component can be flexibly adjusted, the length of the installation component can be flexibly adjusted, and the data acquisition device body is connected to the installation component through the angle adjustment component, thereby realizing the flexible adjustment of the position and angle of the device body, which can meet the different installation environments and data acquisition needs in the production workshop.

[0009] Preferably, the first fixing component further includes a vacuum adsorption unit, which includes an integrated vacuum generator and a vacuum suction cup; the clamping plate has a clamping surface and a fixing surface perpendicular to the clamping surface, and at least two vacuum adsorption units are provided on each fixing surface, and an anti-slip pad is provided on the clamping surface. The advantages are: this invention can achieve fixing by clamping the workshop foundation with a clamping plate, and can also be fixed using a vacuum adsorption unit, allowing for flexible installation according to actual conditions.

[0010] Preferably, the operating end of the adjusting screw is connected to a rotary handle via a flat key for easy operation.

[0011] Preferably, the second fixing component includes a fixing base with a limiting slot that mates with the data acquisition device body, allowing the data acquisition device body to be secured within the limiting slot. The second fixing component also includes a first magnet spaced apart within the limiting slot and a second magnet disposed on the data acquisition device body. The first magnet is preferably a permanent magnet, and the second magnet is preferably made of a ferromagnetic material. The data acquisition device body is attracted and connected via the first and second magnets. Alternatively, for a device body with an ferrometallic shell, it can be directly attracted to the first magnet. The magnetic attraction between the device body and the fixing base makes assembly and disassembly simple and convenient.

[0012] More preferably, the angle adjustment assembly includes a cross shaft, a first shaft fork fixed to the middle of the fixed base, and a second shaft fork fixed to the mounting assembly. The first and second shaft forks each have a pair of fork arms. The fork arms of the first shaft fork are connected to a pair of journals of the cross shaft, and the fork arms of the second shaft fork are connected to another pair of journals of the cross shaft. Any two adjacent journal ends of the cross shaft are provided with threaded heads, and a fastening nut is screwed onto each threaded head. The beneficial effect is that both the first and second shaft forks of this invention can rotate relative to the cross shaft by a certain angle, realizing the adjustment of the relative position of the fixed base and the adjusting cylinder, thereby achieving flexible adjustment of the angle of the equipment body. After adjustment, the fastening nut is used to fix it, meeting the requirements for accurate data acquisition.

[0013] Preferably, one end of the double-ended screw is provided with a knob for easy screwing.

[0014] Compared with the prior art, this utility model is fixed to the fixed foundation in the workshop by the first fixing component, which makes the installation simple and convenient; the position of the equipment body on the second fixing component can be flexibly adjusted, the length of the installation component can be flexibly adjusted, and the equipment body is connected to the installation component through the angle adjustment component, thereby realizing the flexible adjustment of the position and angle of the equipment body, which can meet the different installation environments and data acquisition needs in the production workshop. Attached Figure Description

[0015] Figure 1 This is a schematic diagram of the structure of this utility model.

[0016] Figure 2 This is an internal schematic diagram of the present invention.

[0017] Figure 3 This is a schematic diagram of the first fixing component of this utility model being installed on the mounting component.

[0018] Figure 4 This is a schematic diagram of the first fixing component of this utility model.

[0019] Figure 5 This is a cross-sectional view of the first fixing component of this utility model. Figure 1 .

[0020] Figure 6 This is a cross-sectional view of the first fixing component of this utility model. Figure 2 .

[0021] Figure 7 This is a schematic diagram of the second fixing component of this utility model.

[0022] Figure 8 This is a schematic diagram of the angle adjustment component described in this utility model. Figure 1 .

[0023] Figure 9 This is a schematic diagram of the angle adjustment component described in this utility model. Figure 2 . Detailed Implementation

[0024] The embodiments of this utility model will be described in detail below with reference to the accompanying drawings. These embodiments are implemented based on the technical solution of this utility model and provide detailed implementation methods and specific operation processes. However, the protection scope of this utility model is not limited to the following embodiments.

[0025] It should be noted that in the description of this utility model, relational terms such as "first" and "second" are used only to distinguish one entity or operation from another entity or operation, and do not necessarily require or imply any such actual relationship or order between these entities or operations.

[0026] In the description of this utility model, unless otherwise explicitly specified and limited, the terms "connected" and "linked" should be interpreted broadly. For example, they can refer to a fixed connection, a detachable connection, or an integral connection; they can refer to a mechanical connection or an electrical connection; they can refer to a direct connection or an indirect connection through an intermediate medium; and they can refer to the internal connection of two components. Those skilled in the art can understand the specific meaning of the above terms in this utility model based on the specific circumstances.

[0027] like Figure 1 As shown, this utility model proposes a multi-dimensional adjustable workshop data acquisition device, including a data acquisition device body 1 (using a data acquisition device integrating current, voltage, temperature, and pressure acquisition) and an installation structure. The installation structure includes an installation component 2, two first fixing components 3 fixed to a fixed foundation in the workshop, a second fixing component 4 for fixing the data acquisition device body 1, and an angle adjustment component 5 for adjusting the angle of the data acquisition device body 1. In actual installation, the utility model is first fixed to the fixed foundation in the workshop using the first fixing components 3. The angle adjustment component 5 is used to adjust the angle between the installation component 2 and the second fixing component 4, and the data acquisition device body 1 is then installed on the second fixing component 4. This allows for flexible adjustment of the acquisition device body, enabling it to adapt to changes in the workshop equipment layout and ensuring accurate data acquisition.

[0028] Combination Figure 1-2 As can be seen, the mounting component 2 is a long rod structure, which includes an outer protective cylinder 2.1, an adjusting cylinder 2.2 with internal threads, and an adjusting screw 2.3. One end of the adjusting screw 2.3 is connected to the outer protective cylinder 2.1 through a bearing, so that the adjusting screw 2.3 can rotate relative to the outer protective cylinder 2.1 under force. The adjusting screw 2.3 is threadedly connected to the adjusting cylinder 2.2, which is located inside the outer protective cylinder 2.1 and has a clearance fit with the outer protective cylinder 2.1, so that the adjusting cylinder 2.2 can move axially relative to the outer protective cylinder 2.1 when the adjusting screw 2.3 rotates, thereby adjusting the length of the mounting component 2. One end of the adjusting cylinder 2.2 extends outward from the outer protective cylinder 2.1, and the extended end of the adjusting cylinder 2.2 is connected to the second fixing component 4 through an angle adjusting component 5. The second fixing component 4 can be adjusted by adjusting the position of the adjusting cylinder 2.2. In addition, the operating end of the adjusting screw 2.3 is provided with a rotating handle 2.4 for convenient operation.

[0029] To prevent the adjusting cylinder 2.2 from rotating relative to the outer protective cylinder 2.1 during adjustment, a pair of guide rods 2.5 are installed at the extended end of the adjusting cylinder 2.2, and a pair of linear bearings 2.6 are installed at the end of the outer protective cylinder 2.1, with the guide rods 2.5 passing through the linear bearings 2.6. During adjustment, rotating the adjusting screw 2.3 causes the adjusting cylinder 2.2 to move axially relative to the outer protective cylinder 2.1 because the adjusting screw 2.3 is rotatably connected to the outer protective cylinder 2.1. During this process, the guide pair formed by the guide rods 2.5 and the linear bearings 2.6 effectively prevents the adjusting cylinder 2.2 from twisting during adjustment. The extension and retraction of the adjusting cylinder 2.2 can be achieved by switching the rotation direction of the adjusting screw 2.3, thus allowing for flexible adjustment of the total length of the mounting assembly 2.

[0030] Combination Figure 1-3 It can be seen that a first fixing component 3 is installed at each of the two ends of the outer casing 2.1 to ensure installation stability. Combined with... Figure 4-6 It is known that the first fixing component 3 includes a mounting base 3.1, a double-ended screw 3.2, and a pair of spaced clamping plates 3.3. The mounting base 3.1 is fixedly installed on the outer casing 2.1, and its bottom preferably has an arc-shaped structure with the same diameter as the outer casing 2.1 to increase the contact area between the two and ensure the fixing effect. The mounting base 3.1 has an axially opened mounting hole, and the double-ended screw 3.2 is rotatably installed in the mounting hole through a bearing. One end of the double-ended screw 3.2 is located outside the mounting base 3.1, and a knob is provided at this end for easy rotation. The double-ended screw 3.2 has two threaded sections with opposite thread directions, and a clamping plate 3.3 is screwed onto each threaded section. Since the threads of the double-ended screw 3.2 turn in opposite directions, the two clamping plates 3.3 move in opposite directions when the double-ended screw 3.2 is rotated. The opening and closing of the two clamping plates 3.3 can be achieved by switching the rotation direction of the double-ended screw 3.2, thereby meeting the fixing requirements of this utility model on fixing foundations of different widths or thicknesses and improving the versatility of this utility model.

[0031] In a preferred embodiment of this utility model, to meet the screwing requirements of the clamping plate 3.3 and the double-ended screw 3.2, the clamping plate 3.3 is designed with a T-shaped structure, and its connecting part is threadedly connected to the double-ended screw 3.2 located in the mounting hole. The horizontal part of the clamping plate 3.3 is located on the upper surface of the mounting base 3.1. To ensure high-precision movement of the two clamping plates 3.3, two bolts are installed on the bottom surface of the horizontal part of each clamping plate 3.3 (the bolts on the two clamping plates 3.3 correspond left and right). Two elongated guide holes 3.4 are opened on the mounting base 3.1, and the bolts 3.5 on the two clamping plates 3.3 pass downward through the corresponding guide holes 3.4. In actual fixing, the distance between the two clamping plates 3.3 is adjusted using the double-ended screw 3.2, and the clamping plates 3.3 are used to clamp and fix the foundation. After adjustment, nuts (which can be double nuts) are screwed on each bolt 3.5 of the clamping plate 3.3 to achieve the fastening of the two clamping plates 3.3, ensuring the clamping force and guaranteeing the fixing effect of this utility model in the workshop. In addition, to further ensure the clamping force of the clamping plate 3.3, an anti-slip pad 3.6 (preferably made of rubber) is provided on the clamping surface of the clamping plate 3.3 to increase friction. See Figure 4-6 .

[0032] Combination Figure 5-6 It is understood that the first fixing component 3 also includes a vacuum adsorption unit 3.7, which includes an integrated vacuum generator and a vacuum suction cup; the clamping plate 3.3 also includes a fixing part perpendicular to its clamping surface, and two vacuum adsorption units 3.7 are arranged on the fixing surface of the fixing part. When encountering a smooth installation surface, the present invention can be fixedly installed on the smooth surface of the workshop using the vacuum adsorption unit 3.7. Of course, for the installation situation where the structural column and the wall are connected together, the clamping plate 3.3 and the vacuum adsorption unit 3.7 can be used together for fixing.

[0033] Combination Figure 7 It can be seen that the second fixing component 4 includes a fixing base 4.1, which has a limiting slot that cooperates with the data acquisition device body 1, so that the data acquisition device body 1 is locked in the limiting slot. The fixing base 4.1 has a certain length, allowing adjustment of the relative installation position of the device body.

[0034] The second fixing component 4 also includes a first magnet 4.2 spaced apart within the limiting slot and a second magnet disposed on the data acquisition device body 1. The first magnet 4.2 is preferably a permanent magnet, and the second magnet is preferably made of a ferromagnetic material. During actual installation, the device body can be attached to the mounting base 3.1 by the first magnet 4.2 and the second magnet. Alternatively, for a device body with an ferrometallic shell, it can be directly attached to the first magnet 4.2, enabling detachable installation of the device body and the second fixing component 4, simplifying disassembly.

[0035] Combination Figure 8-9As can be seen, the angle adjustment assembly 5 includes a cross shaft 5.1, a first shaft fork 5.2 fixed to the middle of the fixed base 4.1, and a second shaft fork 5.3 fixed to the extension end of the adjusting cylinder 2.2. The first shaft fork 5.2 has a pair of fork arms, which are connected to a pair of journals of the cross shaft 5.1, and the first shaft fork 5.2 and the pair of journals are clearance-fitted to ensure that the first shaft fork 5.2 can rotate relative to the pair of journals. Similarly, the pair of fork arms of the second shaft fork 5.3 are connected to another pair of journals of the cross shaft 5.1, and the two are clearance-fitted to ensure that the second shaft fork 5.3 can rotate relative to each other. To achieve angle fixation, any two adjacent journal ends of the cross shaft 5.1 are provided with threaded heads, and a fastening nut is screwed onto each threaded head. After adjustment, a fastening nut can be screwed on to fix the angle.

[0036] This invention is installed on a fixed foundation in the workshop via clamping and / or vacuum adsorption, making it particularly suitable for installation under limited installation conditions. The length of the mounting component 2 is flexibly adjustable, and the installation position of the data acquisition device body 1 on the fixed base 4.1 is also flexibly adjustable. The mounting component 2 is perpendicular to the fixed base 4.1, and the angle between the mounting component 2 and the fixed base 4.1 is flexibly adjustable, thereby enabling flexible adjustment of the data acquisition device body 1. When encountering workshop equipment layout issues, the installation position of the device body on this invention can be flexibly adjusted to ensure the accuracy of data acquisition.

[0037] Finally, it should be emphasized that the above description is merely a preferred embodiment of this utility model and is not intended to limit this utility model. Although this utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art can still make modifications to the technical solutions described in the foregoing embodiments without creative effort, or make equivalent substitutions for some of the technical features. Therefore, any modifications, equivalent substitutions, improvements, etc., made within the spirit and principles of this utility model should be included within the protection scope of this utility model.

Claims

1. A multi-dimensional adjustable workshop data acquisition device, comprising a data acquisition device body and an installation structure, characterized in that: The installation structure includes an installation component, at least two first fixing components fixed to a fixed foundation in the workshop, a second fixing component for fixing the data acquisition device body, and an angle adjustment component for adjusting the angle of the data acquisition device body. The mounting assembly is a long rod structure, which includes an outer protective sleeve, an adjusting sleeve with internal threads, and an adjusting screw. One end of the adjusting screw is connected to the outer protective sleeve through a bearing. The adjusting sleeve is located inside the outer protective sleeve and is clearance-fitted with the outer protective sleeve. One end of the adjusting sleeve extends outward from the outer protective sleeve. The extended end of the adjusting sleeve is connected to the second fixing assembly through the angle adjusting assembly. The adjusting screw is threadedly connected to the adjusting sleeve. At least two identical first fixing components are spaced apart on the outer casing. Each component includes a mounting base, a double-ended screw, and a pair of spaced clamps. The mounting base is fixed to the mounting component and has an axially opened mounting hole. The double-ended screw is rotatably disposed in the mounting hole via a bearing. The two threaded sections of the double-ended screw have opposite directions of rotation, and each threaded section is screwed with one of the clamps.

2. The multi-dimensional adjustable workshop data acquisition device according to claim 1, characterized in that: The first fixing component further includes a vacuum adsorption unit, which includes an integrated vacuum generator and a vacuum suction cup; the clamping plate has a clamping surface and a fixing surface perpendicular to the clamping surface, and at least two vacuum adsorption units are provided on each fixing surface, and an anti-slip pad is provided on the clamping surface.

3. The multi-dimensional adjustable workshop data acquisition device according to claim 1, characterized in that: The operating end of the adjusting screw is connected to a rotating handle via a flat key.

4. The multi-dimensional adjustable workshop data acquisition device according to claim 1, characterized in that: The second fixing component includes a fixing base, which has a limiting slot that cooperates with the data acquisition device body, so that the data acquisition device body is locked in the limiting slot; the second fixing component also includes a first magnet disposed at intervals in the limiting slot and a second magnet disposed on the data acquisition device body.

5. The multi-dimensional adjustable workshop data acquisition device according to claim 4, characterized in that: The angle adjustment assembly includes a cross shaft, a first fork fixed to the middle of the fixed base, and a second fork fixed to the mounting assembly. The first fork and the second fork each have a pair of fork arms. The fork arms of the first fork are connected to a pair of journals of the cross shaft, and the fork arms of the second fork are connected to another pair of journals of the cross shaft. Any two adjacent journal ends of the cross shaft are provided with threaded heads, and a fastening nut is screwed onto each threaded head.

6. The multi-dimensional adjustable workshop data acquisition device according to claim 1, characterized in that: A knob is provided at one end of the double-ended screw.