CN113633041A - Protective clothing, control system and protective system - Google Patents

Abstract

The embodiment of the invention provides protective clothing, a control system and a protective system, wherein the protective clothing sequentially comprises a 3D fabric layer, a metal fiber layer and a nano silver ion sterilization fiber fabric layer from inside to outside, and the 3D fabric layer is a fabric layer with a three-dimensional space structure. According to the invention, the problems of poor air permeability, no radiation protection function and low safety of the protective clothing in the related technology are solved, and the effect of improving the safety of the protective clothing is further achieved.

Description

Protective clothing, control system and protective system

Technical Field

The embodiment of the invention relates to the technical field of protective clothing, in particular to protective clothing, a control system and a protective system.

Background

At present, the product in many fields all need pass through various experiments before going on the market, and these experiments often can exert an influence to human health, when using partial instrument to experiment, often can face the danger of instrument radiation, the experimenter need wear protective clothing under this kind of environment and carry out environmental protection and human protection, and what present widely used protective clothing adopted is that the individual layer non-woven fabrics carries out coating or tectorial membrane complex, it is more oppressive after wearing, the gas permeability is poor thereby leading to the travelling comfort poor, and do not have the function of protecting against radiation, influence healthily, also hinder relevant worker to carry out nimble business operations.

Aiming at the problems of poor air permeability, no radiation protection function and the like of protective clothing in the prior art, and low safety, an effective solution is not provided at present.

Disclosure of Invention

The embodiment of the invention provides a protective garment, a control system and a protective system, which at least solve the problems of poor air permeability, no radiation protection function and the like of the protective garment in the related art and low safety.

According to one embodiment of the invention, the protective clothing comprises a 3D fabric layer, a metal fiber layer and a nano silver ion sterilization fiber cloth layer from inside to outside in sequence, wherein the 3D fabric layer is a fabric layer with a three-dimensional space structure.

In an exemplary embodiment, the metal fiber layer is combined with the 3D fabric layer by means of an internal seam, and the nano silver ion sterilization fiber cloth layer is combined with the metal fiber layer by means of a moisture permeable adhesive.

In one exemplary embodiment, the 3D fabric layer is a 3D spacer fabric woven using a warp knitting process.

In an exemplary embodiment, the metal fiber layer is made of special steel.

In one exemplary embodiment, the protective garment comprises a protective garment body, a protective head cover, a protective glove and a protective boot which are integrally connected.

In one exemplary embodiment, soft silica gel is arranged at the joint of the protective clothing main body and the protective gloves, and soft silica gel is arranged at the joint of the protective clothing main body and the protective boots; and rubber pads are arranged on the first preset position on the outer side of the protective glove and the second preset position on the outer side of the protective boot.

In one exemplary embodiment, the protective garment further comprises: a horizontal seam, wherein the horizontal seam is arranged at a third preset position of the protective clothing main body; the magic tape binding belt covers the surface of the transverse strip seam; an upper zipper, wherein the upper zipper is arranged between the cross bar seam and the protective head cover; a lower zipper, wherein the lower zipper is disposed between the cross-piece seam to the protective boot of the protective garment; a foot restraining strap for restraining a junction of the body of the protective garment and the boot; the magic tape inner ring is arranged at the joint of the protective garment main body and the protective gloves; the magic tape ring strip, wherein, the magic tape ring strip set up in prevent on the hand protector with the junction of protective clothing main part.

According to another embodiment of the present invention, there is also provided a control system applied to the protective suit described in any one of the above, the control system including: the sensor is arranged inside the protective clothing and used for acquiring environmental parameters inside the protective clothing; the environment adjusting device is arranged inside the protective clothing and is used for executing a preset operation under the control of the controller; and the controller is arranged inside the protective clothing, is connected with the sensor and the air purification device, and is used for acquiring the environmental parameters and controlling the environmental regulation device based on the environmental parameters.

In one exemplary embodiment, the sensor comprises at least one of: the temperature and humidity sensor is used for acquiring temperature and humidity parameters inside the protective clothing; the oxygen concentration sensor is used for acquiring oxygen concentration parameters inside the protective clothing.

In an exemplary embodiment, the controller is configured to perform at least one of the following operations: under the condition that the sensor comprises the temperature and humidity sensor, the controller is used for acquiring the temperature and humidity parameters and controlling the environment adjusting device to adjust the temperature and humidity in the protective clothing based on the temperature and humidity parameters; and in the case that the sensor comprises the oxygen concentration sensor, the controller is used for acquiring the oxygen concentration parameter and controlling the environment adjusting device to adjust the oxygen concentration in the protective clothing based on the oxygen concentration parameter.

In an exemplary embodiment, the controller is further configured to perform at least one of the following: under the condition that the sensor comprises the temperature and humidity sensor, the controller is used for comparing the temperature and humidity parameter with a first preset threshold value to obtain a first comparison result, and controlling the environment adjusting device to adjust the temperature and humidity in the protective clothing based on the first comparison result; in the case that the sensor includes the oxygen concentration sensor, the controller is configured to compare the oxygen concentration parameter with a second preset threshold to obtain a second comparison result, and control the environmental conditioning device to adjust the oxygen concentration in the protective suit based on the second comparison result.

According to another embodiment of the invention, a protective system is further provided, which comprises any one of the protective clothing and any one of the control systems.

According to the protective clothing, the 3D fabric layer, the metal fiber layer and the nano silver ion sterilization fiber fabric layer are sequentially arranged from inside to outside, and the 3D fabric layer is a fabric layer with a three-dimensional space structure, so that the functions of good air permeability, strong radiation protection capability and strong sterilization capability are realized. The problem of the gas permeability of protective clothing among the correlation technique poor and do not possess security such as radiation protection function low is solved, and then reached the effect that improves the security of protective clothing.

Drawings

FIG. 1 is a schematic view of a protective garment of an embodiment of the present invention;

FIG. 2 is a schematic view of a 3D fabric structure of a protective garment according to an embodiment of the invention;

FIG. 3 is a schematic view of a protective garment according to an embodiment of the invention;

FIG. 4 is a plan view of a protective garment according to an embodiment of the invention;

fig. 5 is a control system workflow diagram according to an embodiment of the invention.

Description of reference numerals:

102-3D fabric layer, 104-metal fiber layer, 106-nano silver ion sterilization fiber cloth layer, 202-3D spacer fabric, 302-protective clothing main body, 304-protective head cover, 306-protective gloves, 402-protective coverall main body, 404-magic tape and belt, 406-upper zipper, 408-lower zipper, 410-protective hat, 412-protective gloves and 414-foot binding belt.

Detailed Description

Hereinafter, embodiments of the present invention will be described in detail with reference to the accompanying drawings in conjunction with the embodiments.

It should be noted that the terms "first," "second," and the like in the description and claims of the present invention and in the drawings described above are used for distinguishing between similar elements and not necessarily for describing a particular sequential or chronological order.

The utility model provides a protective clothing, from interior to exterior include the 3D fabric layer in proper order, the metal fiber layer, and nanometer silver ion fiber cloth layer that disinfects, the 3D fabric layer is for possessing the fabric layer of spatial structure.

Fig. 1 is a schematic structural diagram of a protective garment according to an embodiment of the present invention, and as shown in fig. 1, the protective garment includes three layers (i.e. 001-: the fabric comprises a 3D fabric layer 102, a metal fiber layer 104 and a nano silver ion sterilization fiber cloth layer 106. The nano silver ion sterilization fiber cloth layer 106 is formed by nano technology to nanocrystallize metal silver, and the silver in a nano state increases the contact surface of silver ions and the outside, so that the sterilization capacity of the nano silver ion sterilization fiber cloth layer is qualitatively leaped, a strong sterilization effect can be generated only by using a small amount of nano silver, and 650 kinds of bacteria can be killed within a few minutes. The nano silver ions are used as a latest generation natural antibacterial agent and have lasting antibacterial effect.

In the above embodiment, through providing a protective clothing, and protective clothing includes the 3D fabric layer by interior outside to in proper order, the metal fiber layer, and nanometer silver ion fiber cloth layer that disinfects, and the 3D fabric layer is for the fabric layer that possesses three-dimensional space structure, has realized that the gas permeability is good, the ability of protecting against radiation is strong and the function that the ability of disinfecting is strong. The problem of the gas permeability of protective clothing among the correlation technique poor and do not possess security such as radiation protection function low is solved, and then reached the effect that improves the security of protective clothing.

In an optional embodiment, the metal fiber layer is combined with the 3D fabric layer through an inner seam, and the nano silver ion sterilization fiber cloth layer is combined with the metal fiber layer through a moisture permeable adhesive.

In the above embodiment, the metal fiber layer is combined with the 3D fabric layer in an inner seam mode, and the nano silver ion sterilization fiber cloth layer is combined with the metal fiber layer by adopting the moisture permeable adhesive, so that the effective combination of the three layers is realized, and the quality of the protective clothing is improved.

In an alternative embodiment, the 3D fabric layer is a 3D spacer fabric woven using a warp knitting process.

In the above embodiment, the 3D fabric layer is a 3D spacer fabric 202 woven by using a warp knitting process, as shown in fig. 2, fig. 2 is a schematic view of a 3D fabric structure of the protective garment according to the embodiment of the present invention, optionally, in practical applications, the 3D spacer fabric with a thickness of about 12mm can be woven by using a warp knitting process, and is used as a base fabric of a multifunctional high-shielding electromagnetic radiation protective garment fabric, wherein the 3D fabric layer is made of polyester, and has the advantages of good elasticity, difficulty in deformation, stiffness, easiness in washing, quick drying and the like, a three-dimensional space structure formed by the 3D fabric is beneficial to air circulation, and as shown in fig. 2, the three-dimensional space structure is good in air permeability, beneficial to saving of the fabric, and convenient for flexible movement of workers. Through this embodiment, thereby solved the gas permeability that exists among the correlation technique and poor problem that leads to the travelling comfort relatively poor.

In an optional embodiment, the metal fiber layer is made of special steel.

In the above embodiment, the metal fiber layer is made of special steel, and the metal fiber layer made of special steel sewn in the metal fiber layer has a high-density structure, so that the metal fiber layer has super-strong radiation protection capability. Through this embodiment, can realize the superstrong radiation protection function of protective clothing.

In an alternative embodiment, the protective garment comprises a protective garment body, a protective head cover, protective gloves and protective boots which are integrally connected.

Fig. 3 is a schematic diagram of a protective garment according to an embodiment of the present invention, and as shown in fig. 3, the protective garment includes a protective garment main body 302, a protective head cover 304, a protective glove 306, and a protective boot (not shown in fig. 3) that are integrally connected.

In an optional embodiment, soft silica gel is arranged at the joint of the protective clothing main body and the protective gloves, and soft silica gel is arranged at the joint of the protective clothing main body and the protective boots; and rubber pads are arranged on the first preset position on the outer side of the protective glove and the second preset position on the outer side of the protective boot.

In the embodiment, the sealing performance of the closed design of cuffs, ankles and the like can be improved by arranging the soft silica gel at the joint of the protective clothing main body and the protective gloves and arranging the soft silica gel at the joint of the protective clothing main body and the protective boots; in addition, rubber pads are arranged on the first preset position on the outer side of the protective glove and the second preset position on the outer side of the protective boot.

In an optional embodiment, the protective garment further comprises: a horizontal seam, wherein the horizontal seam is arranged at a third preset position of the protective clothing main body; the magic tape binding belt covers the surface of the transverse strip seam; an upper zipper, wherein the upper zipper is arranged between the cross bar seam and the protective head cover; a lower zipper, wherein the lower zipper is disposed between the cross-piece seam to the protective boot of the protective garment; a foot restraining strap for restraining a junction of the body of the protective garment and the boot; the magic tape inner ring is arranged at the joint of the protective garment main body and the protective gloves; the magic tape ring strip, wherein, the magic tape ring strip set up in prevent on the hand protector with the junction of protective clothing main part.

FIG. 4 is a plan view of a protective garment according to an embodiment of the invention, as shown in FIG. 4, in the above embodiment, the protective garment further comprising: a transverse strip seam (not shown in figure 4), a hook and loop fastener 404, an upper zipper 406, a pull-down chain 408, a foot binding strap 414, a hook and loop fastener inner loop (not shown in figure 4), and a hook and loop fastener strip (not shown in figure 4). The embodiment provides a multifunctional electromagnetic radiation prevention protective garment integrating electromagnetic radiation prevention, ventilation, comfort, antibiosis and convenience in wearing. The wearing method of the protective clothing in the embodiment of the invention is described below with reference to fig. 4:

when the protective suit is worn, the magic tape belt 404 is opened, the upper zipper 406 and the lower zipper 408 are opened through the transverse stripe seam (not shown in fig. 4 and shielded by the magic tape belt 404), the human body is directly attached to the inner wall of the protective suit main body 402 (corresponding to the protective suit main body 302), the upper zipper 406 and the lower zipper 408 are pulled, the magic tape belt 404 is attached to cover the transverse stripe seam, the foot binding band 414 is fastened, the protective cap 410 (corresponding to the protective helmet cover 304) is worn, and the protective gloves 412 (corresponding to the protective gloves 306) are worn to enable the magic tape ring strip (not shown in fig. 4) to be attached to and adhered to the magic tape inner ring (not shown in fig. 4) of the cuff, so that the wearing is quick and convenient.

In this embodiment, a control system is further provided, which is applied to the protective suit described in any one of the above, and the control system includes: the sensor is arranged inside the protective clothing and used for acquiring environmental parameters inside the protective clothing; the environment adjusting device is arranged inside the protective clothing and is used for executing a preset operation under the control of the controller; and the controller is arranged inside the protective clothing, is connected with the sensor and the air purification device, and is used for acquiring the environmental parameters and controlling the environmental regulation device based on the environmental parameters.

In the above embodiment, the control system includes: the sensor is arranged inside the protective clothing and used for acquiring environmental parameters inside the protective clothing, for example, in practical application, the temperature, humidity, oxygen concentration or other environmental parameters inside the protective clothing can be acquired through the sensor; the control system further comprises: the environment adjusting device is arranged inside the protective clothing and used for executing predetermined operation under the control of a controller, for example, in practical application, an air purifying device can be arranged inside the protective clothing and used for executing air purifying operation under the control of the controller, or a temperature and humidity adjusting device can be arranged inside the protective clothing and used for adjusting temperature and humidity parameters inside the protective clothing; optionally, in practical application, other adjusting devices can be arranged inside the protective clothing according to needs; the control system further comprises: the controller is arranged inside the protective clothing, connected with the sensor and the air purification device, and used for acquiring the environmental parameters and controlling the environment adjusting device based on the environmental parameters. In the related technology, a voice communication system, a temperature display instrument and a detachable oxygen bag are arranged on a protective clothing body, the voice communication system can amplify contents to be expressed by a protective clothing wearer through a loudspeaker and transmit the contents to workers matched with the voice communication system, so that the workers can better match with the voice communication system to complete required work, however, the protective clothing still has the problems of low intelligent degree, poor comfort and the like, for example, other workers are required to be matched with the voice communication system when the oxygen bag is replaced, and the protective clothing is not suitable for long-time wearing and the like; through the embodiment, the sensor, the environment adjusting device and the controller are arranged inside the protective clothing, so that the quality of air inside the protective clothing can be improved, the intelligent degree of the protective clothing can be improved, and the problems of low intelligent degree and poor comfort of the protective clothing in the related technology are solved.

In an alternative embodiment, the sensor comprises at least one of: the temperature and humidity sensor is used for acquiring temperature and humidity parameters inside the protective clothing; the oxygen concentration sensor is used for acquiring oxygen concentration parameters inside the protective clothing.

In the above embodiment, the sensor comprises at least one of: the temperature and humidity sensor is used for acquiring temperature and humidity parameters inside the protective clothing; the oxygen concentration sensor is used for acquiring oxygen concentration parameters inside the protective clothing; optionally, in practical application, other sensors may be further disposed inside the protective clothing as required to enhance monitoring of the inside of the protective clothing, so as to further improve the safety of the protective clothing.

In an alternative embodiment, the controller is configured to perform at least one of the following: under the condition that the sensor comprises the temperature and humidity sensor, the controller is used for acquiring the temperature and humidity parameters and controlling the environment adjusting device to adjust the temperature and humidity in the protective clothing based on the temperature and humidity parameters; and in the case that the sensor comprises the oxygen concentration sensor, the controller is used for acquiring the oxygen concentration parameter and controlling the environment adjusting device to adjust the oxygen concentration in the protective clothing based on the oxygen concentration parameter.

In the above embodiment, the controller may be configured to acquire an environmental parameter inside the protective suit, and when the protective suit includes a temperature and humidity sensor inside, the controller may be configured to acquire the temperature and humidity parameter, and control the environment adjusting device to adjust the temperature and humidity inside the protective suit based on the temperature and humidity parameter; and under the condition that the interior of the protective clothing comprises an oxygen concentration sensor, the controller is used for acquiring the oxygen concentration parameter and controlling the environment adjusting device to adjust the oxygen concentration in the protective clothing based on the oxygen concentration parameter. Through this embodiment, realized carrying out the purpose of monitoring to the inside environmental parameter of protective clothing, reached the effect that improves the security of protective clothing.

In an optional embodiment, the controller is further configured to perform at least one of: under the condition that the sensor comprises the temperature and humidity sensor, the controller is used for comparing the temperature and humidity parameter with a first preset threshold value to obtain a first comparison result, and controlling the environment adjusting device to adjust the temperature and humidity in the protective clothing based on the first comparison result; in the case that the sensor includes the oxygen concentration sensor, the controller is configured to compare the oxygen concentration parameter with a second preset threshold to obtain a second comparison result, and control the environmental conditioning device to adjust the oxygen concentration in the protective suit based on the second comparison result.

In the above embodiment, the controller may further adjust the internal environment of the protective suit according to the environmental parameter, and optionally, when the sensor includes a temperature and humidity sensor, the controller may be configured to compare the temperature and humidity parameter with a first preset threshold (a first threshold preset by the controller) to obtain a first comparison result, and control the environmental adjustment device to adjust the temperature and humidity in the protective suit based on the first comparison result; optionally, in a case where the sensor includes the oxygen concentration sensor, the controller may be configured to compare the oxygen concentration parameter with a second preset threshold (a second threshold preset by the controller) to obtain a second comparison result, and control the environment adjusting device to adjust the oxygen concentration in the protective clothing based on the second comparison result, and by setting the first preset threshold and the second preset threshold, the environment condition inside the protective clothing may be effectively monitored, so as to achieve the purpose of effectively preventing risks.

In this embodiment, a protective system is further provided, which includes any one of the protective clothing described above and any one of the control systems described above. In this embodiment, the protection system both includes that the gas permeability that the protective clothing possessed is good, the radiation protection ability is strong and the function that the ability of disinfecting is strong, still includes the intelligent function that can improve the inside air quality of protective clothing and improve the protective clothing that control system possessed simultaneously, has solved the problem that the protective clothing security that exists is low and intelligent degree is low, the travelling comfort is poor among the correlation technique.

It is to be understood that the above-described embodiments are only a few, but not all, embodiments of the present invention.

The present invention will be described in detail with reference to the following examples:

fig. 5 is a schematic diagram of the control system working flow according to the embodiment of the present invention, as shown in fig. 5, the flow includes the following steps:

s502, starting a sensor inside the protective suit;

s504, the sensor detects the internal air data (corresponding to the environmental parameters);

s506, the control system collects sensor data (equivalent to the controller acquiring the environmental parameters collected by the sensor);

s508, the control system analyzes data;

s510, the analysis result of the step S508 is data normal, which is equivalent to that the sensor data collected by the control system does not exceed the first preset threshold or the second preset threshold;

s512, under the condition that the analysis result is that the data is normal, the control system does not perform any processing;

s514, the analysis result of the step S508 is data abnormal, which is equivalent to the sensor data collected by the control system exceeding the first preset threshold or the second preset threshold;

and S516, if the analysis result is that the data is normal, the control system starts the air purification and supply system.

In the embodiment, the temperature and humidity sensor and the oxygen concentration sensor are arranged on the protective clothing body and used for collecting environmental parameters inside the protective clothing; the protective suit body is provided with an air purification and supply system for realizing air exchange between the interior of the protective suit and the outside of the protective suit; the protective suit body is provided with a controller system for analyzing data, controlling an air purification and supply system and exchanging air.

The temperature and humidity/oxygen concentration sensor collects temperature and humidity/oxygen concentration parameters in the protective clothing body and feeds the temperature and humidity/oxygen concentration parameters back to the controller, the processor of the controller compares the parameters with critical values (corresponding to the first preset threshold value and the second preset threshold value), whether the temperature and humidity/oxygen concentration in the protective clothing body reaches the critical values or not is obtained, and when the parameters reach the critical values, the controller controls the air purification and air supply system to start and carry out gas exchange; when the parameter does not reach the critical value, the air purification and supply system is not started. Through this embodiment, can improve the inside air quality of protective clothing, can improve the intelligent degree of protective clothing again, solve the problem that the intelligent degree of protective clothing that exists is low, the travelling comfort is poor among the correlation technique.

By the protective clothing and the control system, the electromagnetic radiation prevention function can be realized, and a wearer can ensure the safety of working in a strong electromagnetic radiation environment for a long time after wearing the protective clothing; by adopting the 3D fabric layer, the comfort can be improved, the flexible business operation of related workers can be facilitated, and the requirements of working environments are met; the protective clothing can realize strong antibacterial property, and the protective clothing is implanted with the nano silver ion antibacterial fiber material, so that the protective clothing has strong antibacterial effect; the effect of quick and convenient wearing can be achieved by arranging the integrated connection and using the magic tape; the air quality in the protective clothing can be guaranteed, and when parameters such as internal oxygen, humidity and temperature are easy to cause discomfort of a wearer, the air quality in the protective clothing can be improved.

It will be apparent to those skilled in the art that the various modules or steps of the invention described above may be implemented using a general purpose computing device, they may be centralized on a single computing device or distributed across a network of computing devices, and they may be implemented using program code executable by the computing devices, such that they may be stored in a memory device and executed by the computing device, and in some cases, the steps shown or described may be performed in an order different than that described herein, or they may be separately fabricated into various integrated circuit modules, or multiple ones of them may be fabricated into a single integrated circuit module. Thus, the present invention is not limited to any specific combination of hardware and software.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention, and various modifications and changes may be made by those skilled in the art. Any modification, equivalent replacement, or improvement made within the principle of the present invention should be included in the protection scope of the present invention.

Claims (12)

1. The protective clothing is characterized by comprising a 3D fabric layer, a metal fiber layer and a nano silver ion sterilization fiber fabric layer from inside to outside in sequence, wherein the 3D fabric layer is a fabric layer with a three-dimensional space structure.

2. The protective garment as claimed in claim 1, wherein said metal fiber layer is bonded to said 3D fabric layer by means of an internal seam, and said layer of nano silver ion sterilizing fiber cloth is bonded to said metal fiber layer by means of a moisture permeable adhesive.

3. The protective garment of claim 1, wherein the 3D fabric layer is a 3D spacer fabric woven using a warp knitting process.

4. The protective garment according to claim 1, wherein the metal fiber layer is made of special steel.

5. The protective garment of claim 1, comprising a protective garment body, a protective head cover, a protective glove, and a protective boot, all integrally connected.

6. The protective garment as claimed in claim 5, wherein soft silica gel is arranged at the joint of the protective garment body and the protective gloves, and soft silica gel is arranged at the joint of the protective garment body and the protective boots; and rubber pads are arranged on the first preset position on the outer side of the protective glove and the second preset position on the outer side of the protective boot.

7. The protective garment as in claim 5, further comprising:

a horizontal seam, wherein the horizontal seam is arranged at a third preset position of the protective clothing main body;

the magic tape binding belt covers the surface of the transverse strip seam;

an upper zipper, wherein the upper zipper is arranged between the cross bar seam and the protective head cover;

a lower zipper, wherein the lower zipper is disposed between the cross-piece seam to the protective boot of the protective garment;

a foot restraining strap for restraining a junction of the body of the protective garment and the boot;

the magic tape inner ring is arranged at the joint of the protective garment main body and the protective gloves;

the magic tape ring strip, wherein, the magic tape ring strip set up in prevent on the hand protector with the junction of protective clothing main part.

8. A control system for use in a protective garment according to any one of claims 1 to 7, the control system comprising:

the sensor is arranged inside the protective clothing and used for acquiring environmental parameters inside the protective clothing;

the environment adjusting device is arranged inside the protective clothing and is used for executing a preset operation under the control of the controller;

and the controller is arranged inside the protective clothing, is connected with the sensor and the environment purifying device, and is used for acquiring the environment parameters and controlling the environment adjusting device based on the environment parameters.

9. The control system of claim 8, wherein the sensor comprises at least one of:

the temperature and humidity sensor is used for acquiring temperature and humidity parameters inside the protective clothing;

the oxygen concentration sensor is used for acquiring oxygen concentration parameters inside the protective clothing.

10. The control system of claim 9, wherein the controller is configured to perform at least one of:

under the condition that the sensor comprises the temperature and humidity sensor, the controller is used for acquiring the temperature and humidity parameters and controlling the environment adjusting device to adjust the temperature and humidity in the protective clothing based on the temperature and humidity parameters;

and in the case that the sensor comprises the oxygen concentration sensor, the controller is used for acquiring the oxygen concentration parameter and controlling the environment adjusting device to adjust the oxygen concentration in the protective clothing based on the oxygen concentration parameter.

11. The control system of claim 9, wherein the controller is further configured to perform at least one of:

under the condition that the sensor comprises the temperature and humidity sensor, the controller is used for comparing the temperature and humidity parameter with a first preset threshold value to obtain a first comparison result, and controlling the environment adjusting device to adjust the temperature and humidity in the protective clothing based on the first comparison result;

in the case that the sensor includes the oxygen concentration sensor, the controller is configured to compare the oxygen concentration parameter with a second preset threshold to obtain a second comparison result, and control the environmental conditioning device to adjust the oxygen concentration in the protective suit based on the second comparison result.

12. A protective system comprising a protective suit according to any one of claims 1 to 7 and a control system according to any one of claims 8 to 11.

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