A cardiac monitoring, diagnosing and treating device
By designing a wire-binding mechanism to automatically collect and limit lead wires, the safety hazards caused by lead wire scattering are solved, thus improving the safety of using the electrocardiograph.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Utility models(China)
- Current Assignee / Owner
- 徐珺晗
- Filing Date
- 2025-01-02
- Publication Date
- 2026-06-09
AI Technical Summary
The leads of existing electrocardiographs are quite long and can easily fall to the ground, posing a tripping hazard to medical staff.
A wire harnessing mechanism was designed, including a connecting block, a limiting component, a support block, a spring component, and a power block. Through the coordinated movement of these components, the automatic collection and limiting of the lead wires are achieved, preventing them from scattering.
It effectively prevents lead wires from scattering, reduces the risk of tripping medical staff, and improves the safety of the working environment.
Smart Images

Figure CN224330952U_ABST
Abstract
Description
Technical Field
[0001] This utility model relates to the field of medical diagnostic and treatment equipment, specifically a cardiology monitoring and treatment device. Background Technology
[0002] An electrocardiograph (ECG) is a medical device used to record the electrical activity of the heart. It plays a vital role in the diagnosis and treatment of cardiovascular diseases. By detecting and mapping the minute electrical changes produced by the heart with each beat, doctors can assess the functional status of the heart, identify potential problems, and guide treatment decisions.
[0003] Current electrocardiogram (ECG) machines have multiple leads connected to the machine. Electrodes are fixed to the side of each lead away from the machine. When medical staff examine a patient, they pull the leads to move them and place the electrodes on the patient's body, allowing the ECG machine to examine the patient. After the examination, the medical staff place the electrodes back on the ECG machine. However, to ensure that the electrodes can fit patients of different body types, the leads are generally quite long. In this case, some leads may fall to the ground, posing a tripping hazard to medical staff when they pass by, thus creating a certain degree of safety risk. Utility Model Content
[0004] To address the shortcomings of existing technologies, this utility model provides a cardiology monitoring and treatment device that solves the problem that lead wires are generally quite long, and in such cases, some lead wires may be scattered on the ground, which could easily cause medical staff to trip and fall, posing a certain degree of safety hazard.
[0005] To achieve the above objectives, this utility model provides the following technical solution: a cardiology monitoring and diagnosis device, including an electrocardiograph, wherein a wire harness mechanism for limiting the lead wires is installed on both sides of the electrocardiograph;
[0006] The wire harness mechanism includes a connecting block, one side of which is fixedly connected to one side of the electrocardiograph. The connecting block has a movable groove for collecting the lead wires inside. A limiting component is also provided inside the connecting block, with one side extending out of the connecting block and the other side extending to the sidewall of the movable groove. The limiting component is slidably connected to both the connecting block and the movable groove. A support block is fixedly provided on one side of the connecting block, with its outer surface slidably connected to the inner surface of the connecting block. A triangular block is provided inside the connecting block, slidably connected to the connecting block. A triangular groove is provided inside the support block, with one side of the triangular block extending into the groove and slidably connected to it. A spring assembly is fixedly provided inside the connecting block on the side away from the triangular block, with one side of the spring assembly slidably connected to the side of the support block away from the triangular block.
[0007] As a preferred technical solution of this utility model, the spring assembly includes a first spring, one side of which is fixedly connected to the inside of the connecting block. A trapezoidal groove is provided on the side of the connecting block away from the triangular block. A trapezoidal block is fixedly provided on the side of the first spring away from the side wall of the connecting block. The trapezoidal block extends into the trapezoidal groove on the side away from the first spring. The outer surface of the trapezoidal block is slidably connected to the inner surface of the trapezoidal groove.
[0008] As a preferred technical solution of this utility model, a movable plate is fixedly provided on the side of the triangular block away from the support block, and a square plate is fixedly provided on one end of the movable plate. The side of the square plate away from the movable plate is fixedly connected to one side of the trapezoidal block.
[0009] As a preferred technical solution of this utility model, a power block is fixedly provided on the side of the movable plate away from the triangular block, and the power block extends out of the interior of the connecting block on the side away from the movable plate, and the outer surface of the power block is slidably connected to the inner surface of the connecting block.
[0010] As a preferred technical solution of this utility model, the limiting component includes a limiting block, one end of which is fixedly connected to one end of the support block, the end of which extends away from the support block into the interior of the connecting block, and one end of which extends to the side wall of the movable groove. The limiting block is slidably connected to the connecting block and the side wall of the movable groove respectively.
[0011] As a preferred technical solution of this utility model, the connecting block has a guide groove inside, the bottom of the support block is fixedly provided with a guide block, the bottom of the guide block extends into the guide groove, and the outer surface of the guide block is slidably connected to the inner surface of the guide groove.
[0012] Compared with the prior art, this utility model provides a cardiology monitoring and treatment device with the following beneficial effects:
[0013] After using the electrocardiograph (ECG) machine to treat a patient, staff collect the ECG leads. Simultaneously, they apply force to a triangular block, driving it into a triangular groove in the support block. The triangular block, through the groove, drives the support block, which in turn drives a spring assembly to retract. This retraction of the support block and the limiting component releases the seal on the movable groove. The collected leads are then moved into the movable groove. The staff then releases the drive of the triangular block and the spring assembly. Due to the spring's elasticity, the spring assembly drives the support block, causing it to move the triangular block out of the groove. Simultaneously, the support block drives the limiting component to extend, sealing the movable groove and limiting the collection of leads within it. This structure effectively limits the collection of leads, preventing them from scattering when the ECG machine is not in use. It also prevents scattered leads from tripping medical staff, reducing safety hazards and ensuring a safer working environment for medical personnel. Attached Figure Description
[0014] Figure 1 A schematic diagram of the overall structure of the cardiology monitoring and treatment device provided by this utility model;
[0015] Figure 2 for Figure 1 The diagram shows the structure of the wire harness mechanism.
[0016] Figure 3 for Figure 1 The diagram shows a cross-sectional structure.
[0017] Figure 4 for Figure 3 The schematic diagram of the limiting component shown Figure 1 ;
[0018] Figure 5 for Figure 3 The schematic diagram of the limiting component shown Figure 2 ;
[0019] Figure 6 for Figure 3 The diagram shows the structure of the connecting block.
[0020] In the diagram: 1. Electrocardiograph; 2. Connecting block; 3. Movable groove; 4. Support block; 5. Triangular block; 6. Triangular groove; 7. First spring; 8. Trapezoidal groove; 9. Trapezoidal block; 10. Movable plate; 11. Square plate; 12. Power block; 13. Limiting block; 14. Guide groove; 15. Guide block. Detailed Implementation
[0021] 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.
[0022] Please see Figures 1-6 In this embodiment: a cardiology monitoring and treatment device includes an electrocardiograph 1. A wire-binding mechanism for limiting the lead wires is installed on both sides of the electrocardiograph 1. The wire-binding mechanism includes a connecting block 2, one side of which is fixedly connected to one side of the electrocardiograph 1. A movable groove 3 for collecting the lead wires is formed inside the connecting block 2. A limiting component is provided inside the connecting block 2, one side of which extends out of the connecting block 2 and to the side wall of the movable groove 3. The limiting component is slidably connected to both the connecting block 2 and the movable groove 3. A support block 4 is fixedly provided on one side of the connecting block 2, and its outer surface is slidably connected to the inner surface of the connecting block 2. A triangular block 5 is provided inside the connecting block 2, and it is slidably connected to the connecting block 2. A triangular groove 6 is formed inside the support block 4, one side of which extends into the triangular groove 6, and it is slidably connected to the triangular groove 6. A spring assembly is fixedly provided inside the connecting block 2 on the side away from the triangular block 5, and one side of the spring assembly is slidably connected to the side of the support block 4 away from the triangular block 5.
[0023] The spring assembly includes a first spring 7, one side of which is fixedly connected to the interior of the connecting block 2. A trapezoidal groove 8 is provided on the side of the connecting block 2 away from the triangular block 5. A trapezoidal block 9 is fixedly provided on the side of the first spring 7 away from the side wall of the connecting block 2. The trapezoidal block 9 extends into the interior of the trapezoidal groove 8 on the side away from the first spring 7. The outer surface of the trapezoidal block 9 is slidably connected to the inner surface of the trapezoidal groove 8. A movable plate 10 is fixedly provided on the side of the triangular block 5 away from the support block 4. A square plate 11 is fixedly provided at one end of the movable plate 10. The side of the square plate 11 away from the movable plate 10 is fixedly connected to the side of the trapezoidal block 9. A power block 12 is fixedly provided on the side of the movable plate 10 away from the triangular block 5. The side of the power block 12 away from the movable plate 10 extends out of the interior of the connecting block 2. The outer surface of the power block 12 is slidably connected to the inner surface of the connecting block 2.
[0024] The limiting component includes a limiting block 13. One end of the limiting block 13 is fixedly connected to one end of the support block 4. The end of the limiting block 13 away from the support block 4 extends out of the interior of the connecting block 2, and the other end of the limiting block 13 extends to the side wall of the movable groove 3. The limiting block 13 is slidably connected to the side wall of the connecting block 2 and the movable groove 3 respectively. A guide groove 14 is provided inside the connecting block 2. A guide block 15 is fixedly provided at the bottom of the support block 4. The bottom of the guide block 15 extends into the interior of the guide groove 14, and the outer surface of the guide block 15 is slidably connected to the inner surface of the guide groove 14.
[0025] When the support block 4 moves in the connecting block 2, the support block 4 will drive the guide block 15 to move inside the guide groove 14. The guide block 15 limits the support block 4 through the guide groove 14 to prevent the support block 4 from deviating at an angle during movement. When the trapezoidal block 9 leaves the trapezoidal groove 8 or the triangular block 5 leaves the triangular groove 6, a part of the structure of either the trapezoidal block 9 or the triangular groove 6 is still inside the triangular groove 6 or the trapezoid. This setting ensures that the triangular block 5 or the trapezoidal block 9 can smoothly enter the triangular groove 6 or the trapezoidal groove 8 at any time.
[0026] The working principle and usage process of this utility model are as follows: After the staff finishes using the electrocardiograph 1 to diagnose and treat the patient, the staff collects the leads of the electrocardiograph 1. At the same time, the staff applies pressure to the power block 12, causing the power block 12 to drive the square plate 11 to move through the movable plate 10. The square plate 11 drives the trapezoidal block 9 to leave the trapezoidal groove 8, releasing the drive on the support block 4. The support block 4 drives the first spring 7 to be in a compressed state. At the same time, the movable plate 10 drives the triangular block 5 to move, causing the triangular block 5 to enter the triangular groove 6 of the support block 4. The triangular block 5 drives the support block 4 to move through the inclined surface of the triangular groove 6, causing the support block 4 to drive the limiting block 13 to retract, thus releasing the limiting block 13. In addition to sealing the movable slot 3, the staff moves the collected lead wires into the movable slot 3. Then, the staff releases the drive of the power block 12 and the first spring 7. According to the spring's extensibility, the first spring 7 drives the trapezoidal block 9 to move, causing the trapezoidal block 9 to drive the movable plate 10 through the square plate 11. At the same time, the movable plate 10 drives the triangular block 5 into the triangular slot 6, releasing the drive of the triangular block 5 on the support block 4. Simultaneously, the first spring 7 drives the trapezoidal block 9 into the trapezoidal slot 8. The trapezoidal block 9 drives the limiting block 13 to extend through the inclined surface of the trapezoidal slot 8, so that the limiting block 13 completes the sealing of the movable slot 3 and simultaneously completes the collection and limiting of the lead wires inside the movable slot 3.
[0027] Finally, it should be noted that the above description is merely a preferred embodiment of this utility model and is not intended to limit the utility model. Although the utility model has been described in detail with reference to the foregoing embodiments, those skilled in the art can still modify the technical solutions described in the foregoing embodiments or make equivalent substitutions for some of the technical features. 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 cardiology monitoring and diagnosis device, characterized in that: Includes an electrocardiograph (1), wherein the electrocardiograph (1) is equipped with a wire harness mechanism on both sides for limiting the lead wires; The wire harness mechanism includes a connecting block (2), one side of which is fixedly connected to one side of the electrocardiograph (1). The connecting block (2) has an internal movable groove (3) for collecting the lead wires. A limiting component is provided inside the connecting block (2), one side of which extends out of the connecting block (2) and to the side wall of the movable groove (3). The limiting component is slidably connected to both the connecting block (2) and the movable groove (3). A support block (4) is fixedly provided on one side of the connecting block (2). The outer surface of the support block (4) is slidably connected to the inner surface of the connecting block (2). The connecting block (2) has a triangular block (5) inside, which is slidably connected to the connecting block (2). The support block (4) has a triangular groove (6) inside, one side of the triangular block (5) extends into the triangular groove (6), and the triangular block (5) is slidably connected to the triangular groove (6). A spring assembly is fixedly provided on the side of the connecting block (2) away from the triangular block (5), and one side of the spring assembly is slidably connected to the side of the support block (4) away from the triangular block (5).
2. The cardiology monitoring and diagnosis device according to claim 1, characterized in that: The spring assembly includes a first spring (7), one side of which is fixedly connected to the inside of the connecting block (2). A trapezoidal groove (8) is provided on the side of the connecting block (2) away from the triangular block (5). A trapezoidal block (9) is fixedly provided on the side of the first spring (7) away from the side wall of the connecting block (2). The trapezoidal block (9) extends into the trapezoidal groove (8) on the side away from the first spring (7). The outer surface of the trapezoidal block (9) is slidably connected to the inner surface of the trapezoidal groove (8).
3. The cardiology monitoring and diagnosis device according to claim 2, characterized in that: The triangular block (5) is fixedly provided with a movable plate (10) on the side away from the support block (4), and a square plate (11) is fixedly provided at one end of the movable plate (10). The side of the square plate (11) away from the movable plate (10) is fixedly connected to the side of the trapezoidal block (9).
4. The cardiology monitoring and treatment device according to claim 3, characterized in that: A power block (12) is fixedly provided on the side of the movable plate (10) away from the triangular block (5). The power block (12) extends out of the interior of the connecting block (2) on the side away from the movable plate (10). The outer surface of the power block (12) is slidably connected to the inner surface of the connecting block (2).
5. A cardiology monitoring and diagnosis device according to claim 4, characterized in that: The limiting component includes a limiting block (13), one end of which is fixedly connected to one end of the support block (4), the end of which extends away from the support block (4) extends out of the interior of the connecting block (2), and the other end of which extends to the side wall of the movable groove (3). The limiting block (13) is slidably connected to the connecting block (2) and the side wall of the movable groove (3) respectively.
6. The cardiology monitoring and diagnosis device according to claim 5, characterized in that: The connecting block (2) has a guide groove (14) inside, and the bottom of the support block (4) is fixedly provided with a guide block (15). The bottom of the guide block (15) extends into the guide groove (14), and the outer surface of the guide block (15) is slidably connected to the inner surface of the guide groove (14).