A portable glove integrity testing device

CN224398920UActive Publication Date: 2026-06-23BEIJING NEURONBC LAB CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Utility models(China)
Current Assignee / Owner
BEIJING NEURONBC LAB CO LTD
Filing Date
2025-07-28
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

Existing glove integrity testing devices are prone to glove deformation and leakage during inflation due to air bladder expansion, resulting in inaccurate test results.

Method used

The system employs components such as a detection support body, first and second air supply pipes, limiting grooves, elastic bands or ropes, rollers, and patch-type air pressure sensors. By using a closed space and stable air pressure, it achieves the sealing test of the inside of the glove, reducing air leakage and deformation, and accurately detecting the integrity of the glove.

Benefits of technology

This improved the stability and accuracy of glove testing, reduced air leakage and finger scratches, and enhanced the reliability and precision of test results.

✦ Generated by Eureka AI based on patent content.

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Abstract

This utility model belongs to the field of glove testing technology, specifically a portable on-site glove integrity testing device, including a testing support body; a first air supply pipe is opened inside the testing support body; a one-way valve is connected to the end of the first air supply pipe; multiple second air supply pipes are opened inside the testing support body; by using a rubber band or rope to tighten the outside of the glove and tighten the glove onto the first limiting groove of the testing support body, all the second air supply pipes can be located inside the glove. At this time, a closed space is formed inside the glove, which stabilizes the air pressure inside the glove and thus achieves the stability of the test results. At the same time, when the rubber band or rope is tightened on the outside of the glove, even if there are wrinkles in some parts of the glove, the wrinkles will be completely tightened between the rubber band or rope and the first limiting groove, reducing the problem of air leakage between the glove and the testing support body.
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Description

Technical Field

[0001] This utility model belongs to the field of glove testing technology, specifically a portable on-site glove integrity testing device. Background Technology

[0002] A portable glove integrity field testing device is a tool used to quickly detect whether protective gloves (such as medical gloves) have damage or micropores. It typically uses the conductivity method to detect the integrity of the glove by applying an electric current.

[0003] In a glove integrity tester with publication number CN215811472U, mainly used for glove seal testing, the display screen, wireless charging module, RFID module, pressure sensor I, pressure sensor II, air pump I, air pump II, and solenoid valve are centrally mounted on an integrated circuit board. This maximizes the use of space in the housing and glove bracket, resulting in high space utilization and reducing the size of the glove integrity tester, thus facilitating glove integrity testing. The handle is also convenient for carrying and picking up for testing. This invention solves the problems of cumbersome and inconvenient testing and the inability to wirelessly charge the device. The aforementioned prior art uses multiple solenoid valves to control the air pumps to inflate the inside of the glove for testing. However, in this device, the inflatable sealing ring needs to be fully expanded to effectively seal the inner wall of the glove, thus enabling the detection of the internal air pressure.

[0004] In existing technologies, gloves are tested by applying electricity or inflating them to check their integrity. However, some testing devices are found to seal the inner wall of the glove by inserting the device inside and inflating an internal air bladder to perform air pressure testing. This process can lead to deformation of the glove due to air bladder expansion and gaps, resulting in air leakage and inaccurate test results.

[0005] Therefore, this utility model provides a portable glove integrity testing device. Utility Model Content

[0006] In order to overcome the shortcomings of the prior art, at least one technical problem raised in the background art is solved.

[0007] The technical solution adopted by this utility model to solve its technical problem is as follows: A portable on-site glove integrity testing device of this utility model includes a testing support body; a first air supply pipe is provided inside the testing support body; a one-way valve is connected to the end of the first air supply pipe; multiple second air supply pipes are provided inside the testing support body; the first air supply pipe is connected to the second air supply pipes; a first limiting groove is provided on the side wall of the testing support body; multiple first limiting grooves are provided on the testing support body; by using the testing support body to directly test the glove, a portable glove integrity testing device is achieved. The testing process involves simultaneously securing the gloves with rubber bands or ropes to the outside, placing them within the first limiting groove of the testing support body. This ensures that all second air supply tubes are located inside the gloves, creating a closed space that stabilizes the internal air pressure and consequently the test results. Furthermore, when the gloves are secured with rubber bands or ropes between the rubber bands or ropes and the first limiting groove, any wrinkles will be contained within the groove, reducing air leakage between the gloves and the testing support body and thus ensuring stable testing of the gloves.

[0008] Furthermore, the second air supply pipe is connected to an air guide pipe at its end; an extension pipe is sleeved at the end of the air guide pipe; a second limiting groove is provided on the side wall of the extension pipe; multiple second limiting grooves are provided on the extension pipe; by attaching a rubber band or rope to the position outside the second limiting groove, isolation is achieved; at this time, the fingers and body of the isolation glove can be detected inside a single finger during the process of the second air supply pipe inflating the glove, so as to know which fingers are intact and which are damaged, thus achieving accurate detection of the glove.

[0009] Furthermore, the end of the extension tube is provided with multiple slots; rollers are rotatably connected inside the slots; the rollers reduce the problem of the inner wall of the fingers being scratched when the glove is put on the detection support body, thereby ensuring the integrity of the inner wall of the glove when it is being tested.

[0010] Furthermore, a patch-type air pressure sensor is installed on the side wall of the detection support body; by installing a patch-type air pressure sensor on the detection support body, when a glove is put on the detection support body and inflation is completed, the air pressure inside the glove can be detected by the patch-type air pressure sensor, so as to obtain more accurate complete glove data.

[0011] Furthermore, multiple guide frames are fixed to the side wall of the detection support body; the guide frames cover the top of the patch-type barometric pressure sensor on the detection support body; by providing guide frames on the detection support body, the direct contact between the glove and the patch-type barometric pressure sensor can be reduced when the glove is put on the detection support body, thereby reducing the problem of incorrect detection results of the patch-type barometric pressure sensor caused by the glove being attached to the patch-type barometric pressure sensor, and improving the stability of the patch-type barometric pressure sensor during operation.

[0012] Furthermore, an elastic limiting band is fitted onto the detection support body; the position of the elastic limiting band corresponds to the first limiting groove; by fitting the elastic limiting band onto the detection support body, the glove fitted onto the detection support body can be fixed using the elastic limiting band. Since the elastic limiting band corresponds to the opening of the first limiting groove, the sealing performance of the glove fitted onto the detection support body can be further improved, thereby further improving the accuracy of the glove's detection results.

[0013] The beneficial effects of this utility model are as follows:

[0014] 1. The portable glove integrity testing device of this utility model directly tests the glove using a testing support body, achieving portable testing of glove integrity. Simultaneously, by using a rubber band or rope to secure the glove to the outside and then to the first limiting groove of the testing support body, all second air supply tubes are located inside the glove, forming a closed space inside the glove. This stabilizes the internal air pressure, thus ensuring stable test results. Furthermore, when the rubber band or rope is used to secure the glove to the outside, even if there are wrinkles in parts of the glove, these wrinkles will be completely contained within the rubber band or rope and the first limiting groove, reducing air leakage between the glove and the testing support body, thereby ensuring stable testing of the glove.

[0015] 2. The portable glove integrity field testing device of this utility model achieves isolation by attaching an elastic band or rope to the outside of the second limiting groove; at this time, the fingers of the isolated glove are separated from the main body, and the internal structure of each finger can be tested during the inflation of the glove into the glove through the second air supply tube, so as to determine which fingers are intact and which fingers are damaged, thus achieving accurate testing of the glove. Attached Figure Description

[0016] The present invention will be further described below with reference to the accompanying drawings.

[0017] Figure 1 This is a perspective view of the present invention;

[0018] Figure 2 This is a cross-sectional view of the present invention;

[0019] Figure 3 This is a cross-sectional view of the air outlet pipe in this utility model;

[0020] Figure 4 This is the front view of this utility model;

[0021] Figure 5 This is a schematic diagram of an inflatable block fitted with an elastic limiting band.

[0022] Figure 6 This is a cross-sectional view of the elastic limiting band;

[0023] In the diagram: 1. Detection support body; 11. First air supply pipe; 12. One-way valve; 13. Second air supply pipe; 14. First limiting groove; 2. Air guide pipe; 21. Extension pipe; 22. Second limiting groove; 3. Slot; 31. Roller; 4. Patch-type air pressure sensor; 5. Guide frame; 6. Elastic limiting band. Detailed Implementation

[0024] To make the technical means, creative features, objectives and effects of this utility model easier to understand, the present utility model will be further described below in conjunction with specific embodiments.

[0025] like Figures 1 to 2As shown in the embodiment of this utility model, a portable glove integrity testing device includes a testing support body 1; a first air supply pipe 11 is provided inside the testing support body 1; a one-way valve 12 is connected to the end of the first air supply pipe 11; multiple second air supply pipes 13 are provided inside the testing support body 1; the first air supply pipe 11 and the second air supply pipes 13 are connected; a first limiting groove 14 is provided on the side wall of the testing support body 1; multiple first limiting grooves 14 are provided on the testing support body 1; during operation, the one-way valve 12 is first connected to a device that can deliver gas (including but not limited to air pumps, fans, and gas tanks, etc.), then the testing support body 1 is inserted into the glove to be tested, then the end of the glove is placed at the position of the first limiting groove 14, and then a rubber band or rope is used to tighten the outside of the glove, with the rubber band or rope located at the corresponding position of the first limiting groove 14. At this time, the glove is tightened on the first limiting groove 14. Then, the gas delivery device is turned on to send gas into the first gas delivery pipe 11. At this time, the gas can be sent into the glove to be tested through the second gas delivery pipe 13. Then, observe whether the glove leaks or deforms to obtain the on-site test results of the glove. By using the test support body 1 to directly test the glove, the integrity of the glove can be tested in a portable manner. At the same time, by using a rubber band or rope to tighten the outside of the glove and tightening the glove into the first limiting groove 14 of the test support body 1, all the second gas delivery pipes 13 can be located inside the glove. At this time, a closed space is formed inside the glove, which stabilizes the air pressure inside the glove and thus achieves the stability of the test results. At the same time, when the rubber band or rope is tightened on the outside of the glove, it is located between the rubber band or rope and the first limiting groove 14. Even if there are wrinkles in some parts of the glove, the wrinkles will be completely tightened between the rubber band or rope and the first limiting groove 14, reducing the problem of air leakage between the glove and the test support body 1, and thus achieving stable testing of the glove.

[0026] like Figure 3 As shown, the second air supply pipe 13 is connected to an air guide pipe 2 at its end; an extension pipe 21 is sleeved at the end of the air guide pipe 2; a second limiting groove 22 is provided on the side wall of the extension pipe 21; the second limiting groove 22 has multiple grooves on the extension pipe 21; by providing a set of air guide pipes 2 and extension pipes 21 at the end of each second air supply pipe 13, when the glove to be tested is worn on the detection support body 1, the finger position of the glove to be tested can be isolated from the glove body. Here, as needed, several fingers can be tested, and the ends of several fingers can be constricted; this isolation is achieved by attaching a rubber band or rope to the position outside the second limiting groove 22; at this time, the fingers of the glove are isolated from the body, and during the process of the second air supply pipe 13 inflating the glove, the inside of a single finger can be detected, and it can be determined which fingers are intact and which are damaged, thus achieving accurate detection of the glove.

[0027] like Figure 3 As shown, the extension tube 21 has multiple slots 3 at its end; a roller 31 is rotatably connected inside the slot 3; by providing multiple rollers 31 at the end of the extension tube 21, when the glove is put on the detection support body 1, and the air duct 2 and the extension tube 21 are inserted into the inside of the fingers of the glove, the rollers 31 contact the inner wall of the fingers of the glove, replacing the sliding contact between the extension tube 21 and the fingers with the rolling contact between the rollers 31 and the inner wall of the fingers. By setting the rollers 31, the problem of the inner wall of the fingers being scratched when the glove is put on the detection support body 1 can be reduced, thereby ensuring the integrity of the inner wall of the glove when it is being tested.

[0028] like Figure 3 As shown, a patch-type air pressure sensor 4 is installed on the side wall of the detection support body 1. By installing the patch-type air pressure sensor 4 on the detection support body 1, when a glove is put on the detection support body 1 and inflation is completed, the air pressure inside the glove can be detected by the patch-type air pressure sensor 4, so as to obtain more accurate complete glove data.

[0029] like Figure 3 As shown, multiple guide frames 5 are fixed to the side wall of the detection support body 1; the guide frames 5 cover the top of the patch-type barometric pressure sensor 4 on the detection support body 1; by providing guide frames 5 on the detection support body 1, the direct contact between the glove and the patch-type barometric pressure sensor 4 can be reduced when the glove is put on the detection support body 1, thereby reducing the problem of incorrect detection results of the patch-type barometric pressure sensor 4 due to the glove being attached to the patch-type barometric pressure sensor 4, and improving the stability of the patch-type barometric pressure sensor 4 during operation.

[0030] like Figure 3 As shown, an elastic limiting band 6 is fitted onto the detection support body 1; the position of the elastic limiting band 6 corresponds to the first limiting groove 14; by fitting the elastic limiting band 6 onto the detection support body 1, the glove fitted onto the detection support body 1 can be fixed using the elastic limiting band 6. Since the elastic limiting band 6 corresponds to the opening of the first limiting groove 14, the sealing performance of the glove fitted onto the detection support body 1 can be further improved, thereby further improving the accuracy of the glove's detection results.

[0031] During operation, first connect the one-way valve 12 to a gas-transmitting device (including but not limited to air pumps, fans, and gas cylinders). Then, insert the detection support body 1 into the glove to be tested. Next, place the end of the glove in the first limiting groove 14. Then, use a rubber band or rope to tighten the outside of the glove, with the rubber band or rope positioned in the corresponding position of the first limiting groove 14. At this point, the glove is tightened in the first limiting groove 14. Then, turn on the gas delivery device to send gas into the first gas delivery pipe 11. At this time, the gas can be sent into the glove to be tested through the second gas delivery pipe 13. Then, observe whether the glove leaks or deforms to obtain the on-site test results of the glove. The support body 1 directly inspects the glove, enabling portable inspection of its integrity. Simultaneously, a rubber band or rope is used to secure the glove to the outside, placing it within the first limiting groove 14 of the support body 1. This ensures all second air supply tubes 13 are located inside the glove, creating a closed space and stabilizing the internal air pressure, thus ensuring stable test results. Furthermore, when the rubber band or rope is secured to the outside of the glove, even if there are wrinkles in some areas, they will be completely contained within the groove, reducing air leakage between the glove and the support body 1, thereby ensuring stable glove inspection. By providing a set of air guide tubes 2 and extension tubes 21 at the end of each second air supply tube 13, when the glove to be tested is placed on the testing support body 1, the finger positions of the glove to be tested can be isolated from the glove body. The number of fingers to be tested can be determined as needed, and the ends of the fingers can be constricted accordingly. This isolation is achieved by attaching an elastic band or rope to the position outside the second limiting groove 22. At this time, the fingers of the glove are isolated from the body, and the internal structure of a single finger can be tested during the inflation of the glove by the second air supply tube 13. This allows it to be determined which fingers are intact and which are damaged, thus achieving accurate testing of the glove. By providing multiple rollers 31 at the end of the extension tube 21, when the glove is placed on the detection support body 1 and the air duct 2 and extension tube 21 extend into the inside of the glove's fingers, the rollers 31 contact the inner wall of the glove's fingers. This replaces the sliding contact between the extension tube 21 and the fingers with the rolling contact between the rollers 31 and the inner wall of the fingers. The rollers 31 reduce the risk of scratches on the inner wall of the fingers when the glove is on the detection support body 1, thus ensuring the integrity of the inner wall of the glove during testing. Furthermore, by installing a patch-type air pressure sensor 4 on the detection support body 1, when the glove is placed on the detection support body 1 and inflation is complete, the patch-type air pressure sensor 4 can detect the air pressure inside the glove, obtaining more accurate data on the glove's integrity.By providing a guide frame 5 on the detection support body 1, direct contact between the glove and the patch-type pressure sensor 4 can be reduced when the glove is placed on the detection support body 1. This reduces the possibility of erroneous detection results from the patch-type pressure sensor 4 due to the glove being attached to it, thus improving the stability of the patch-type pressure sensor 4 during operation. By attaching an elastic limiting band 6 to the detection support body 1, the glove can be secured to the detection support body 1. Because the elastic limiting band 6 corresponds to the opening of the first limiting groove 14, the sealing of the glove on the detection support body 1 is further improved, further enhancing the accuracy of the glove's detection results.

[0032] The foregoing has shown and described the basic principles, main features, and advantages of this utility model. Those skilled in the art should understand that this utility model is not limited to the above embodiments. The embodiments and descriptions in the specification are merely illustrative of the principles of this utility model. Various changes and modifications can be made to this utility model without departing from its spirit and scope, and all such changes and modifications fall within the scope of the claimed utility model. The scope of protection of this utility model is defined by the appended claims and their equivalents.

Claims

1. A portable glove integrity testing device, comprising a testing support body (1); wherein a first air supply pipe (11) is provided inside the testing support body (1); characterized in that: The first gas supply pipe (11) is connected to a one-way valve (12) at its end; the detection support body (1) has multiple second gas supply pipes (13) inside; the first gas supply pipe (11) is connected to the second gas supply pipes (13); the detection support body (1) has a first limiting groove (14) on its side wall; the first limiting groove (14) has multiple grooves on the detection support body (1).

2. The portable glove integrity testing device according to claim 1, characterized in that: The second gas supply pipe (13) is connected to a gas guide pipe (2) at its end; an extension pipe (21) is sleeved at the end of the gas guide pipe (2); a second limiting groove (22) is provided on the side wall of the extension pipe (21); the second limiting groove (22) is provided in multiple places on the extension pipe (21).

3. The portable glove integrity testing device according to claim 2, characterized in that: The extension tube (21) has multiple slots (3) at its end; a roller (31) is rotatably connected inside the slot (3).

4. The portable glove integrity testing device according to claim 1, characterized in that: A patch-type air pressure sensor (4) is installed on the side wall of the detection support body (1).

5. The portable glove integrity testing device according to claim 4, characterized in that: The detection support body (1) has multiple guide frames (5) fixed to its side wall; the guide frames (5) cover the top of the patch-type air pressure sensor (4) on the detection support body (1).

6. The portable glove integrity testing device according to claim 1, characterized in that: The detection support body (1) is fitted with an elastic limiting band (6); the position of the elastic limiting band (6) corresponds to the first limiting groove (14).