Integrated electromagnetic heater with shock detection
By introducing a shock absorber structure with damping springs and damping telescopic rods into the electromagnetic heater, the problem of equipment being easily damaged in a vibration environment is solved, and higher accuracy and reliability of vibration detection are achieved.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- JIANGSU RUILILONG ELECTRIC EQUIP CO LTD
- Filing Date
- 2025-05-27
- Publication Date
- 2026-06-26
AI Technical Summary
Existing integrated electromagnetic heaters for vibration detection lack physical vibration protection structures and cannot effectively protect the equipment from damage under external vibration.
The shock absorber structure, which combines damping springs and damping telescopic rods, improves equipment stability and enhances the accuracy of vibration detection by buffering and absorbing vibrations.
It effectively mitigates vibration damage to equipment, improves the reliability and accuracy of vibration detection, and ensures that equipment can issue timely alarms during critical vibrations.
Smart Images

Figure CN224418971U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of electromagnetic heater technology, specifically an integrated electromagnetic heater for shock detection. Background Technology
[0002] The integrated electromagnetic heater with vibration detection is a device that integrates vibration detection functionality into a traditional electromagnetic heater. This detection function uses vibration sensors and other devices installed inside the device to monitor vibration levels in real time. Once abnormal vibration is detected, the system will promptly issue an alarm or take appropriate protective measures, such as stopping heating, to prevent equipment damage or safety accidents caused by vibration.
[0003] However, although electromagnetic heaters with anti-vibration detection function have anti-vibration detection function, they lack physical anti-vibration protection structure, which makes it impossible to protect the machine itself from vibration when external vibration occurs. In view of the above situation, we will carry out technical innovation on the basis of existing integrated electromagnetic heaters with anti-vibration detection. Utility Model Content
[0004] The purpose of this invention is to provide an integrated electromagnetic heater for shock detection, so as to solve the problems mentioned in the background art.
[0005] To achieve the above objectives, this utility model provides the following technical solution: an integrated electromagnetic heater for shock detection, comprising:
[0006] An integrated electromagnetic heater for vibration detection is provided. A base is placed beneath the heater, and damping telescopic rods are evenly placed on the top of the base. A shock-absorbing spring is placed around the outer ring of each damping telescopic rod, and a positioning tube is placed around the outer ring of each shock-absorbing spring. The positioning tubes are evenly distributed on the top of the base, and a buffer liner is slidably fitted around the outer ring of each positioning tube. A connecting sleeve is provided around the outer ring of the buffer liner, and the connecting sleeves are evenly distributed at the bottom of the integrated electromagnetic heater. A connecting ring is fitted around the outer ring of the telescopic end of the damping telescopic rod.
[0007] Preferably, the bottom of the base has countersunk holes evenly distributed throughout, the bottom of the damping telescopic rod has threaded holes, a cross bolt is installed in the countersunk holes, and the cross bolt is screwed into the threaded holes.
[0008] Preferably, a first through hole is provided on the outer side of the telescopic end of the connecting ring and the damping telescopic rod, and a second through hole is provided on the outer side of the connecting sleeve and the buffer liner. Bolts are provided in the first and second through holes, and nuts are screwed onto the outer side of the bolts. The nuts are located on the left side of the connecting sleeve.
[0009] Preferably, the top of the connecting ring is fitted with the top of the inner sidewall of the connecting sleeve, the outer sidewall of the connecting ring is fitted with the inner sidewall of the buffer liner, and the bottom of the base is uniformly provided with anti-slip pads.
[0010] Preferably, a set of mounting holes is provided on both the front and rear sides of the inner sidewall of the connecting ring, a spring is provided in the mounting hole, and a round-headed pin is provided on the outside of the spring.
[0011] Preferably, a set of positioning holes is provided on both the front and rear sides of the telescopic end of the damping telescopic rod, and the round head part of the round head pin is inserted into the positioning hole.
[0012] Compared with the prior art, the beneficial effects of this utility model are as follows:
[0013] This invention utilizes a shock absorber composed of a shock-absorbing spring and a damping telescopic rod to mitigate damage to the internal components of the integrated shock-absorbing and detection electromagnetic heater caused by vibrations. It also improves the accuracy of the integrated shock-absorbing and detection electromagnetic heater in detecting vibrations that affect the operation of the device.
[0014] When the damping telescopic rod and shock absorber spring fail due to prolonged use, they can be disassembled and replaced simply by unscrewing the bolts and Phillips head bolts, thereby improving the ease of component replacement. Attached Figure Description
[0015] Figure 1 This is a schematic diagram of the structure of an integrated electromagnetic heater for shock detection according to the present invention;
[0016] Figure 2 This is a partial cross-sectional view of the front of an integrated electromagnetic heater for shock detection according to the present invention.
[0017] Figure 3 This is a partial cross-sectional view of the right side of an integrated electromagnetic heater for shock detection according to this utility model.
[0018] In the diagram: 1. Integrated electromagnetic heater for shock absorption and detection; 11. Base; 12. Anti-slip pad; 13. Cross bolt; 14. Positioning tube; 15. Damping telescopic rod; 16. Shock-absorbing spring; 17. Connecting sleeve; 18. Buffer liner; 19. Connecting ring; 2. Bolt; 21. Nut; 22. Spring; 23. Round head pin. Detailed Implementation
[0019] 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.
[0020] Please see Figures 1-3 An integrated electromagnetic heater for vibration detection includes an integrated electromagnetic heater 1 for vibration detection. A base 11 is placed below the integrated electromagnetic heater 1. Damping telescopic rods 15 are evenly placed on the top of the base 11. A shock-absorbing spring 16 is placed around the outer ring of the damping telescopic rod 15. A positioning tube 14 is placed around the outer ring of the shock-absorbing spring 16. The positioning tube 14 is evenly and fixedly positioned on the top of the base 11. A buffer liner 18 is slidably sleeved around the outer ring of the positioning tube 14. A connecting sleeve 17 is fixedly positioned around the outer ring of the buffer liner 18. The connecting sleeve 17 is evenly and fixedly positioned at the bottom of the integrated electromagnetic heater 1. A connecting ring 19 is sleeved around the telescopic end of the damping telescopic rod 15. A countersunk hole is evenly and evenly opened through the bottom of the base 11. A threaded hole is opened at the bottom of the damping telescopic rod 15. A cross bolt 13 is rotatably installed in the countersunk hole. Bolt 13 is screwed into the threaded hole. The damping telescopic rod 15 and the shock-absorbing spring 16 are placed into the positioning tube 14, and the shock-absorbing spring 16 is located on the outer ring of the damping telescopic rod 15. Then, the cross bolt 13 passes through the countersunk hole of the base 11 and is screwed into the threaded hole of the damping telescopic rod 15 to fix the damping telescopic rod 15 to the top of the base 11. The connecting ring 19 and the telescopic end of the damping telescopic rod 15 are provided with a first through hole. The connecting sleeve 17 and the buffer liner 18 are provided with a second through hole. Bolt 2 is installed in the first through hole and the second through hole. Nut 21 is screwed into the outside of the bolt 2. Nut 21 is located on the left side of the connecting sleeve 17. The top of the connecting ring 19 is in contact with the top of the inner side wall of the connecting sleeve 17. The outer side wall of the connecting ring 19 is in contact with the inner side wall of the buffer liner 18. Anti-slip pads 12 are evenly provided on the bottom of the base 11.
[0021] A set of mounting holes is provided on both the front and rear sides of the inner wall of the connecting ring 19. A spring 22 is installed in the mounting hole, and a round-headed pin 23 is provided on the outer side of the spring 22. The elastic force of the spring 22 must be greater than the frictional force between the connecting ring 19 and the buffer liner 18. A set of positioning holes is provided on both the front and rear sides of the telescopic end of the damping telescopic rod 15. The round head of the pin 23 is inserted into the positioning hole. The connecting ring 19 is sleeved on the outer ring of the telescopic end of the damping telescopic rod 15. The spring 22 drives the pin 23 to insert into the positioning hole of the connecting ring 19, thereby limiting the connecting ring 19 to the outer ring of the telescopic end of the damping telescopic rod 15. This connects the first through hole on the outer side of the connecting ring 19 and the damping telescopic rod 15. Then, the connecting ring 19 and the positioning tube 14 are inserted upward into the buffer liner 18. When the first through hole of the connecting ring 19 and the damping telescopic rod 15 is aligned with the second through hole of the connecting sleeve 17 and the buffer liner 18, the bolt 2 can be used. The connecting ring 19 is screwed into the first and second through holes and connected to the nut 21, thereby fixing the connecting ring 19 to the outer ring of the telescopic end of the damping telescopic rod 15 and fixing the connecting ring 19 inside the connecting sleeve 17. When vibration occurs, the shock absorber formed by the shock-absorbing spring 16 and the damping telescopic rod 15 can alleviate the damage caused by vibration to the internal components of the integrated anti-vibration detection electromagnetic heater 1. By buffering and absorbing most of the external environmental vibration and some non-critical self-vibration, the integrated anti-vibration detection electromagnetic heater 1 is in a relatively stable state. Thus, when a large vibration that may actually damage the equipment or affect its normal operation occurs, the anti-vibration detection function is not easily interfered with or confused by other irrelevant vibrations. It can more accurately detect these vibrations that need attention and issue corresponding signals or alarms in a timely manner, allowing staff to take timely measures, thereby improving the reliability of detection.
[0022] Working principle: The damping telescopic rod 15 and the shock-absorbing spring 16 are placed inside the positioning tube 14, with the shock-absorbing spring 16 positioned on the outer ring of the damping telescopic rod 15. Then, a cross bolt 13 is threaded through the countersunk hole of the base 11 and connected to the threaded hole of the damping telescopic rod 15, thus fixing the damping telescopic rod 15 to the top of the base 11. The connecting ring 19 is fitted onto the outer ring of the telescopic end of the damping telescopic rod 15. The spring 22 drives the round-headed pin 23 to insert into the positioning hole of the connecting ring 19, thus limiting the connecting ring 19 to the outer ring of the telescopic end of the damping telescopic rod 15, thereby connecting the connecting ring 19 and the first through hole on the outer side of the damping telescopic rod 15. Then, the connecting ring 19 and the positioning tube 14 are inserted upwards into the buffer liner 18. When the first through hole of the connecting ring 19 and the damping telescopic rod 15 is aligned with the second through hole of the connecting sleeve 17 and the buffer liner 18, the bolt 2 can be used to penetrate the first and second through holes. The hole is screwed into the nut 21, thereby fixing the connecting ring 19 to the outer ring of the telescopic end of the damping telescopic rod 15 and fixing the connecting ring 19 inside the connecting sleeve 17. When vibration occurs, the shock absorber formed by the shock-absorbing spring 16 and the damping telescopic rod 15 can alleviate the damage caused by vibration to the internal components of the integrated anti-vibration detection electromagnetic heater 1. By buffering and absorbing most of the external environmental vibration and some non-critical self-vibration, the integrated anti-vibration detection electromagnetic heater 1 is in a relatively stable state. Thus, when a large vibration that may actually damage the equipment or affect its normal operation occurs, the anti-vibration detection function is not easily interfered with or confused by other irrelevant vibrations. It can more accurately detect these vibrations that need attention and issue corresponding signals or alarms in a timely manner, allowing staff to take timely measures, thereby improving the reliability of detection.
[0023] When the damping telescopic rod 15 and the shock-absorbing spring 16 fail due to prolonged use, simply unscrew the bolt 2 to move the damping telescopic rod 15 and the connecting ring 19 downwards to separate them from the connecting sleeve 17. Then, pull the connecting ring 19 off the telescopic end of the damping telescopic rod 15, and unscrew the cross bolt 13. At this point, the damping telescopic rod 15 and the shock-absorbing spring 16 can be moved upwards to remove them from the base 11 for replacement.
Claims
1. A shock detection integrated electromagnetic heater, characterized by, include: An integrated electromagnetic heater for vibration detection (1) is provided. A base (11) is placed below the integrated electromagnetic heater for vibration detection (1). A damping telescopic rod (15) is evenly placed on the top of the base (11). A shock-absorbing spring (16) is placed on the outer ring of the damping telescopic rod (15). A positioning tube (14) is placed on the outer ring of the shock-absorbing spring (16). The positioning tube (14) is evenly arranged on the top of the base (11). A buffer liner (18) is slidably sleeved on the outer ring of the positioning tube (14). A connecting sleeve (17) is provided on the outer ring of the buffer liner (18). The connecting sleeve (17) is evenly arranged on the bottom of the integrated electromagnetic heater for vibration detection (1). A connecting ring (19) is sleeved on the outer ring of the telescopic end of the damping telescopic rod (15).
2. The shock detection integrated electromagnetic heater of claim 1, wherein: The bottom of the base (11) is uniformly provided with countersunk holes, and the bottom of the damping telescopic rod (15) is provided with threaded holes. A cross bolt (13) is provided in the countersunk holes and is screwed into the threaded holes.
3. The shock detection integrated electromagnetic heater of claim 2, wherein: The connecting ring (19) and the extension end of the damping telescopic rod (15) are provided with a first through hole, and the connecting sleeve (17) and the buffer liner (18) are provided with a second through hole. Bolts (2) are provided in the first and second through holes, and nuts (21) are screwed onto the outside of the bolts (2). The nuts (21) are located on the left side of the connecting sleeve (17).
4. The shock detection integrated electromagnetic heater of claim 1, wherein: The top of the connecting ring (19) is in contact with the top of the inner wall of the connecting sleeve (17), the outer wall of the connecting ring (19) is in contact with the inner wall of the buffer liner (18), and the bottom of the base (11) is uniformly provided with anti-slip pads (12).
5. The shock detection integrated electromagnetic heater of claim 1, wherein: The inner sidewall of the connecting ring (19) is provided with a set of mounting holes on both the front and rear sides. A spring (22) is provided in the mounting hole, and a round-headed pin (23) is provided on the outer side of the spring (22).
6. The shock detection integrated electromagnetic heater of claim 5, wherein: The damping telescopic rod (15) has a set of positioning holes on both the front and rear sides of its telescopic end, and the round head part of the round head pin (23) is inserted into the positioning hole.