An uninterrupted power supply type electrode storage container
By designing an uninterrupted power supply type welding electrode insulation cylinder, which uses a combination of heating components and storage batteries for power supply, continuous heating and temperature control of the welding electrode are achieved. This solves the problem of insufficient insulation of welding electrode cylinders in welding equipment, improves welding efficiency, and reduces labor intensity.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- CHINA NUCLEAR IND FIFTH CONSTR CO LTD
- Filing Date
- 2025-05-08
- Publication Date
- 2026-06-09
Smart Images

Figure CN224333639U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of welding equipment technology, and in particular to a welding electrode insulation cylinder with uninterrupted power supply. Background Technology
[0002] The welding electrodes used in manual arc welding often suffer from deterioration in performance due to moisture absorption, resulting in unstable arcs, increased spatter, and defects such as porosity and cracks in the weld. In this condition, the electrodes need to be heated and dried. Furthermore, the electrodes must be kept at a certain temperature during use, placing high demands on the insulation performance of the electrode holder. Currently used electrode holders are unable to maintain this insulation for extended periods, requiring welders to frequently remove electrodes, reducing welding efficiency and increasing their workload. Utility Model Content
[0003] In view of this, in order to solve the above problems, the purpose of this utility model is to provide an uninterrupted power supply type welding rod insulation cylinder, comprising:
[0004] The device comprises an outer cylinder, an inner cylinder, a cover, a partition plate, a heat insulation layer, a battery, a heating assembly, a charging connector, and a control unit. The outer cylinder contains a receiving space. The partition plate is installed in the receiving space and divides the receiving space into an upper chamber and a lower chamber. An opening is formed at the upper end of the outer cylinder, communicating with the upper chamber. The cover is placed over the opening. The inner cylinder is installed within the upper chamber. The outer wall of the inner cylinder and the inner wall of the upper chamber form an installation space. The heating assembly is installed within this installation space. The battery is installed within the lower chamber. The heat insulation layer is disposed on the inner wall of the lower chamber. The charging connector and the control unit are both installed on the outer wall of the outer cylinder. The heating assembly, the charging connector, and the battery are all connected to the control unit.
[0005] In another preferred embodiment, the heating assembly includes a heating wire and a temperature sensor. The heating wire is wound around the outer wall of the inner cylinder, and the temperature sensor is mounted on the partition plate. The temperature sensor has a temperature detection end for detecting the temperature inside the inner cylinder. Both the heating wire and the temperature sensor are connected to the control unit.
[0006] In another preferred embodiment, the heating wire is spirally wound around the outer wall of the inner cylinder.
[0007] In another preferred embodiment, it further includes: a thermal insulation material, which is filled within the installation space.
[0008] In another preferred embodiment, the control unit includes: a housing, a display screen, a plurality of control buttons, and a circuit main board. One surface of the housing is mounted on the outer wall of the outer cylinder, the display screen and the plurality of control buttons are both mounted on the other surface of the housing, the plurality of control buttons are all arranged on one side of the display screen, the circuit main board is mounted inside the housing, the display screen and the plurality of control buttons are both connected to the circuit main board, and the circuit main board is connected to the storage battery.
[0009] In another preferred embodiment, it further includes: a handle, the handle is arranged in a "冂" shape, and the lower end of the handle is rotatably mounted on the outer wall of the outer cylinder.
[0010] In another preferred embodiment, it further includes: a positioning rod and two positioning disks. The positioning rod and the two positioning disks are both placed inside the inner cylinder. The two positioning disks are both mounted on the positioning rod, the two positioning disks are arranged vertically, the two positioning disks are coaxial with the positioning rod, and a plurality of positioning holes are formed in each positioning disk, and the plurality of positioning holes on the two positioning disks are arranged in pairs opposite to each other.
[0011] Due to the adoption of the above technical solutions, the positive effects of the present utility model compared with the prior art are as follows: By applying the present utility model, an uninterruptible power supply type electrode insulation cylinder is provided. The external power supply makes the heating component work through the charging connector, or makes the heating component work through the storage battery, so as to continuously heat the inner cylinder, improve the heat preservation performance and heat preservation time, and further ensure the temperature of the electrode and improve the welding efficiency. Description of the Drawings
[0012] Figure 1 It is an overall schematic diagram of an uninterruptible power supply type electrode insulation cylinder of the present utility model.
[0013] In the drawings: 1. Outer cylinder; 2. Inner cylinder; 3. Cover body; 4. Partition board; 5. Heat insulation and heat preservation layer; 6. Storage battery; 7. Charging connector; 8. Upper chamber; 9. Lower chamber; 10. Heating wire; 11. Temperature sensor; 12. Housing; 13. Display screen; 14. Control button; 15. Handle; 16. Positioning rod; 17. Positioning disk; 18. Positioning hole. Detailed Embodiments
[0014] The present utility model will be further described below in conjunction with the drawings and specific embodiments, but it shall not be construed as a limitation to the present utility model.
[0015] As Figure 1 shown, an uninterruptible power supply type electrode insulation cylinder of a preferred embodiment is shown, including:
[0016] The outer cylinder 1 comprises an inner cylinder 2, a cover 3, a partition plate 4, a heat insulation layer 5, a battery 6, a heating assembly, a charging connector 7, and a control unit. The outer cylinder 1 has an accommodating space. The partition plate 4 is installed in the accommodating space and divides the accommodating space into an upper chamber 8 and a lower chamber 9. An opening is opened at the upper end of the outer cylinder 1, which communicates with the upper chamber 8. The cover 3 is placed over the opening. The inner cylinder 2 is installed in the upper chamber 8. The outer wall of the inner cylinder 2 and the inner wall of the upper chamber 8 form an installation space. The heating assembly is installed in the installation space. The battery 6 is installed in the lower chamber 9. The heat insulation layer 5 is disposed on the inner wall of the lower chamber 9. The charging connector 7 and the control unit are both installed on the outer wall of the outer cylinder 1. The heating assembly, the charging connector 7, and the battery 6 are all connected to the control unit.
[0017] In actual use, the cover 3 is opened, the welding rod is placed inside the inner cylinder 2, and then the cover 3 is closed. The external power supply activates the heating component through the charging connector 7 to heat the inner cylinder 2, thereby heating the welding rod. The temperature of the heating component is controlled by the control unit to keep the inner cylinder 2 at an appropriate temperature. When the external power supply activates the heating component through the charging connector 7, the battery 6 is charged simultaneously. When there is no external power supply, the heating component is activated through the battery 6 to keep the temperature inside the inner cylinder 2 at the required temperature, ensuring continuous heating of the welding rod. The heat insulation layer 5 of the lower chamber 9 prevents the temperature inside the lower chamber 9 from becoming too high, ensuring the safety of the battery 6.
[0018] Furthermore, in a preferred embodiment, the heating assembly includes a heating wire 10 and a temperature sensor 11. The heating wire 10 is wound around the outer wall of the inner cylinder 2, and the temperature sensor 11 is mounted on the partition plate 4. The temperature sensor 11 has a temperature detection end for detecting the temperature inside the inner cylinder 2. Both the heating wire 10 and the temperature sensor 11 are connected to the control unit. Furthermore, the inner cylinder 2 is heated by the heating wire 10, and the temperature inside the inner cylinder 2 is monitored by the detection end of the temperature sensor 11 to ensure the temperature inside the inner cylinder 2 is maintained.
[0019] Furthermore, in a preferred embodiment, the heating wire 10 is spirally wound around the outer wall of the inner cylinder 2. This spiral winding of the heating wire 10 ensures more uniform heating of the inner cylinder 2, guaranteeing a better heating effect.
[0020] Furthermore, as a preferred embodiment, it also includes: a thermal insulation material, which is filled within the installation space. Furthermore, the thermal insulation material prevents temperature loss from the heating wire 10, ensuring the heating effect of the heating wire 10 on the inner cylinder 2.
[0021] Further, as a preferred embodiment, the control unit includes: a housing 12, a display screen 13, a plurality of control buttons 14, and a circuit main board. One surface of the housing 12 is mounted on the outer wall of the outer cylinder 1. The display screen 13 and the plurality of control buttons 14 are both mounted on the other surface of the housing 12. The plurality of control buttons 14 are all arranged on one side of the display screen 13. The circuit main board is mounted inside the housing 12. The display screen 13 and the plurality of control buttons 14 are both connected to the circuit main board, and the circuit main board is connected to the storage battery 6. Further, the heating wire 10 is controlled by the plurality of control buttons 14, and thus the temperature inside the inner cylinder 2 is controlled, and the temperature inside the inner cylinder 2 is displayed through the display screen 13, so as to facilitate real-time observation and adjustment.
[0022] Further, as a preferred embodiment, it further includes: a handle 15. The handle 15 is arranged in a "冂" shape, and the lower end of the handle 15 is rotatably mounted on the outer wall of the outer cylinder 1. Further, the handle 15 facilitates the carrying of the heat preservation cylinder. Furthermore, a plurality of universal wheels are mounted at the lower end of the outer cylinder 1 to facilitate the movement of the heat preservation cylinder.
[0023] Further, as a preferred embodiment, it further includes: a positioning rod 16 and two positioning disks 17. The positioning rod 16 and the two positioning disks 17 are both placed inside the inner cylinder 2. The two positioning disks 17 are both mounted on the positioning rod 16. The two positioning disks 17 are arranged vertically, and the two positioning disks 17 are coaxially arranged with the positioning rod 16. A plurality of positioning holes 18 are formed in each positioning disk 17, and the plurality of positioning holes 18 on the two positioning disks 17 are arranged in pairs opposite to each other. Further, during actual use, when the welding rod is placed inside the inner cylinder 2, the lower end of the welding rod sequentially passes through the corresponding positioning holes 18 on the two positioning disks 17 from top to bottom, so as to facilitate the separate placement of the welding rods and ensure the heating of the welding rods.
[0024] The above are only the preferred embodiments of the present invention, and thus do not limit the implementation manners and protection scope of the present invention. For those skilled in the art, it should be realized that all the equivalent replacements and obvious changes made by using the description and illustrations of the present invention should be included in the protection scope of the present invention.
Claims
1. A welding electrode insulation cylinder with uninterrupted power supply, characterized in that, Comprising: An outer cylinder, an inner cylinder, a cover body, a partition plate, a heat insulation layer, a storage battery, a heating component, a charging connector and a control unit. There is an accommodation space inside the outer cylinder. The partition plate is installed in the accommodation space and divides the accommodation space into an upper chamber and a lower chamber. An opening is provided at the upper end of the outer cylinder, and the opening communicates with the upper chamber. The cover body covers the opening. The inner cylinder is installed in the upper chamber. An installation space is formed between the outer wall of the inner cylinder and the inner wall of the upper chamber. The heating component is installed in the installation space. The storage battery is installed in the lower chamber. The heat insulation layer is provided on the inner wall of the lower chamber. The charging connector and the control unit are both installed on the outer wall of the outer cylinder. The heating component, the charging connector and the storage battery are all connected to the control unit.
2. The uninterrupted power supply type welding rod insulation cylinder according to claim 1, characterized in that, The heating component includes: a heating wire and a temperature sensor. The heating wire is wound around the outer wall of the inner cylinder. The temperature sensor is installed on the partition plate. The temperature sensor has a temperature detection end, and the temperature detection end is used to detect the temperature inside the inner cylinder. The heating wire and the temperature sensor are both connected to the control unit.
3. The uninterrupted power supply type welding rod insulation cylinder according to claim 2, characterized in that, The heating wire is spirally wound around the outer wall of the inner cylinder.
4. The uninterrupted power supply type welding rod insulation cylinder according to claim 1, characterized in that, It further includes: A heat insulation and insulation material, which is filled in the installation space.
5. The uninterrupted power supply type welding rod insulation cylinder according to claim 1, characterized in that, The control unit includes: a housing, a display screen, a plurality of control buttons and a circuit main board. One surface of the housing is installed on the outer wall of the outer cylinder. The display screen and the plurality of control buttons are both installed on the other surface of the housing. The plurality of control buttons are all arranged on one side of the display screen. The circuit main board is installed inside the housing. The display screen and the plurality of control buttons are both connected to the circuit main board. The circuit main board is connected to the storage battery.
6. The uninterrupted power supply type welding rod insulation cylinder according to claim 1, characterized in that, It further includes: A handle, which is arranged in a "冂" shape, and the lower end of the handle is rotatably installed on the outer wall of the outer cylinder.
7. The uninterrupted power supply type welding rod insulation cylinder according to claim 1, characterized in that, It further includes: A positioning rod and two positioning disks. The positioning rod and the two positioning disks are both placed inside the inner cylinder. The two positioning disks are both installed on the positioning rod. The two positioning disks are arranged vertically. The two positioning disks are coaxially arranged with the positioning rod. A plurality of positioning holes are provided on each positioning disk, and the plurality of positioning holes on the two positioning disks are arranged in pairs opposite to each other.