CN211590193U - Robot protective clothing with temperature control function - Google Patents

Abstract

The utility model discloses a robot protective clothing with temperature control function, including installation base, outer inoxidizing coating, interior inoxidizing coating and cold wind air-supply line, the nested outer inoxidizing coating of installing in upper end of installation base, and the up end bolt of installing the base installs seal gasket to seal gasket is connected with the lower extreme of outer inoxidizing coating, the outside of installation base is run through and is installed out the tuber pipe, and goes out the terminal of tuber pipe and the inboard of outer inoxidizing coating and put through mutually, the inboard bonding connection of outer inoxidizing coating has the supporting shoe, and inoxidizing coating in the lower extreme fixedly connected with of supporting shoe, the air vent has been seted up to the terminal surface of interior inoxidi. This robot protective clothing with temperature control function through the gas at the inside reciprocating motion of circulating channel for under operating condition, let the temperature of robot remain throughout below 40, the inside of protective clothing keeps the malleation simultaneously, utilizes air conditioner cold wind at protective clothing inlayer circulation, reaches homothermal effect.

Description

Robot protective clothing with temperature control function

Technical Field

The utility model relates to a robot protective clothing technical field specifically is a robot protective clothing with temperature control function.

Background

The robot works under the high temperature environment, the range of the environment temperature is above 60 degrees, the normal work of the robot is seriously influenced by the working environment, in order to solve the difficult problem that the robot is not suitable for working under the temperature range, a temperature control protective clothing is needed to be adopted to ensure that the robot can normally work under the bearable temperature, but the existing robot protective clothing has certain defects, such as:

the existing robot protective clothing does not have a good constant temperature function, so that the protective efficiency of the existing robot protective clothing has certain defects, and the existing robot protective clothing cannot ensure the sealing and butt joint degree according to the requirements of a working environment, so that the phenomenon of gas leakage occurs, and further certain use defects exist;

in order to solve the problems, innovative design is urgently needed on the basis of the original robot protective clothing structure.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a robot protective clothing with temperature control function to what provide among the above-mentioned background art does not possess better constant temperature function, leads to its protection efficiency to have certain defect, can't guarantee its sealed butt joint degree according to operational environment's demand, leads to its problem that the phenomenon of gas leakage appears.

In order to achieve the above object, the utility model provides a following technical scheme: a robot protective clothing with a temperature control function comprises a mounting base, an outer protective layer, an inner protective layer and a cold air inlet pipe, wherein the outer protective layer is nested at the upper end of the mounting base, a sealing gasket is mounted on an upper end face bolt of the mounting base and is connected with the lower end of the outer protective layer, an air outlet pipe is installed on the outer side of the mounting base in a penetrating mode, the tail end of the air outlet pipe is communicated with the inner side of the outer protective layer, a supporting block is connected to the inner side of the outer protective layer in a bonding mode, the lower end of the supporting block is fixedly connected with the inner protective layer, the inner protective layer is connected with the outer protective layer, an air vent is formed in the outer surface of the tail end of the inner protective layer, a circulating channel is formed between the inner protective layer and the outer protective layer, a butt joint, and the cold air inlet pipe is communicated with the circulating channel, the inner surface of the cold air inlet pipe is connected with a constant temperature layer in an adhering mode, the outer surface of the constant temperature layer is fixedly connected with a lug, and the lug is connected with the inner surface of the cold air inlet pipe.

Preferably, the outer protective layer is provided with a limiting groove and a fireproof layer, the inner side of the outer protective layer is provided with the limiting groove, and the fireproof layer is embedded and installed on the outer side of the limiting groove.

Preferably, the flame retardant coating is the cotton material of glass, and the surface of flame retardant coating is the concave-convex structure setting to the flame retardant coating passes through the spacing groove and constitutes unsmooth cooperation with the inboard of outer inoxidizing coating.

Preferably, the inner protective layer is of a ring-shaped structure, the inner protective layer is made of a hydrophobic coating material, and the inner side of the inner protective layer and the inner side of the outer protective layer form a nested structure.

Preferably, the supporting blocks are made of elastic rubber, 3 supporting blocks are arranged at equal intervals relative to the central point of the inner protective layer, and the inner protective layer and the inner side of the outer protective layer form an elastic structure through the supporting blocks.

Preferably, the cold air inlet pipe is in an L-shaped structure in front view, and the cold air inlet pipe and the constant temperature layer form a clamping structure through a bump,

compared with the prior art, the beneficial effects of the utility model are that: the robot protective clothing with the temperature control function;

1. the robot is provided with a circulating channel, the temperature of the robot is always kept below 40 ℃ in a working state through gas reciprocating in the circulating channel, meanwhile, positive pressure is kept in the protective clothing, air conditioning cold air is circulated in the inner layer of the protective clothing in a circulating mode, the cooling effect is achieved, the flexible material of the protective clothing is matched to meet the operation range of each shaft of the robot, and when the protective clothing and a temperature control system break down, emergency measures are taken, and the application range and the constant temperature effect of the whole device are improved;

2. the double-layer protection layer butt joint structure is arranged, the inner layer of the protection layer is made of a waterproof material with a hydrophobic coating, the outer layer of the protection layer is made of a fireproof material made of glass wool, the waterproof and high-temperature-resistant characteristics are achieved, the inner layer and the outer layer are isolated, and therefore air conditioning air forms circulating airflow.

Drawings

FIG. 1 is a schematic front sectional view of the present invention;

FIG. 2 is a schematic cross-sectional view of the air vent of the present invention;

FIG. 3 is a side sectional structural view of the support block of the present invention;

FIG. 4 is a schematic cross-sectional view of the outer protective layer of the present invention;

fig. 5 is a schematic cross-sectional view of the cold air inlet duct of the present invention.

In the figure: 1. installing a base; 2. an outer protective layer; 201. a limiting groove; 202. a fire barrier layer; 3. sealing gaskets; 4. an air outlet pipe; 5. an inner protective layer; 6. a vent hole; 7. a circulation channel; 8. a support block; 9. A butt joint port; 10. a constant temperature layer; 11. a bump; 12. and a cold air inlet pipe.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-5, the present invention provides a technical solution: a robot protective clothing with a temperature control function comprises a mounting base 1, an outer protective layer 2, a sealing gasket 3, an air outlet pipe 4, an inner protective layer 5, an air vent 6, a circulating channel 7, a supporting block 8, a butt joint 9, a constant temperature layer 10, a convex block 11 and a cold air inlet pipe 12, wherein the outer protective layer 2 is nested and mounted at the upper end of the mounting base 1, the sealing gasket 3 is mounted on an upper end face bolt of the mounting base 1, the sealing gasket 3 is connected with the lower end of the outer protective layer 2, the outer side of the mounting base 1 is provided with the air outlet pipe 4 in a penetrating mode, the tail end of the air outlet pipe 4 is communicated with the inner side of the outer protective layer 2, the supporting block 8 is connected to the inner side of the outer protective layer 2 in a bonding mode, the inner protective layer 5 is fixedly connected with the lower end of the supporting block, and a circulation channel 7 is arranged between the inner protective layer 5 and the outer protective layer 2, the tail end of the outer protective layer 2 is provided with a butt joint 9, the outer side of the outer protective layer 2 is provided with a cold air inlet pipe 12 in a penetrating way, the cold air inlet pipe 12 is communicated with the circulation channel 7, the inner surface of the cold air inlet pipe 12 is connected with a constant temperature layer 10 in an adhering way, the outer surface of the constant temperature layer 10 is fixedly connected with a lug 11, and the lug 11 is connected with the inner surface of the cold air inlet pipe 12.

The outer protective layer 2 is provided with a limiting groove 201 and a fireproof layer 202, the inner side of the outer protective layer 2 is provided with the limiting groove 201, the fireproof layer 202 is embedded in the outer side of the limiting groove 201, the fireproof layer 202 is made of glass wool, the outer surface of the fireproof layer 202 is arranged in a concave-convex structure, the fireproof layer 202 is in concave-convex fit with the inner side of the outer protective layer 2 through the limiting groove 201, the contact area between the fireproof layer 202 and the inner side of the outer protective layer 2 can be further increased through the fireproof layer 202 in the concave-convex structure, and the fireproof and high-temperature-resistant characteristics are further stably achieved;

the inner protective layer 5 is of a ring-shaped structure, the inner protective layer 5 is made of hydrophobic coating materials, the inner sides of the inner protective layer 5 and the outer protective layer 2 form a nested structure, and the inner protective layer 5 made of hydrophobic coating materials can stably realize waterproof work on the inner side of the whole device, so that the phenomenon of water seepage is avoided;

the supporting blocks 8 are made of elastic rubber, 3 supporting blocks 8 are arranged at equal intervals relative to the central point of the inner protective layer 5, the inner protective layer 5 and the inner side of the outer protective layer 2 form an elastic structure through the supporting blocks 8, and the circulating channel 7 between the inner protective layer 5 and the outer protective layer 2 can be stably supported through the elastic rubber supporting blocks 8 which are uniformly distributed;

the cold air inlet pipe 12 is in an L-shaped structure in front view, the cold air inlet pipe 12 and the constant temperature layer 10 form a clamping structure through the convex block 11, and the constant temperature layer 10 can stably perform constant temperature treatment on the air conducted by the cold air inlet pipe 12, so that the phenomenon of temperature emission is avoided.

The working principle is as follows: when the robot protective clothing with the temperature control function is used, according to the figure 1, the device is firstly placed at a position needing to work, then the cold air inlet pipe 12 is butted with an external air-conditioning and cold air supply device, at the moment, the cold air inlet pipe 12 transmits the transmitted cold air to the surface of the robot along the inner side of the inner protective layer 5, and then the cold air circularly flows in an interlayer between the surface of the robot and the inner protective layer 5, so that the cold air of the air conditioner circularly flows in the inner layer of the protective clothing to achieve the effect of cooling (an experimental result shows that when the environmental temperature is 40 ℃, the circulating air of the air conditioner can be reduced to 25 ℃, a small amount of condensation exists on the inner layer surface of the protective clothing, but the robot cannot be influenced), when the circulating air in the device reaches a certain pressure, the device can stably discharge work along the air outlet pipe 4, the inner protective layer 5 is made of a waterproof material with a hydrophobic coating, the outer protective layer 2 is made of a fireproof material made of glass wool, the waterproof and high-temperature-resistant characteristics are realized, meanwhile, the inner layer and the outer layer are isolated through the rubber supporting blocks 8 which are uniformly distributed, so that air conditioning air forms circulating air flow, meanwhile, the whole protective clothing is convenient to detach, the installation time is about 30-50 minutes, a set of protective clothing is suggested, when the protective clothing cannot meet the working requirements (air leakage, breakage and the like), the protective clothing can be replaced in time, and the whole practicability is improved.

Those not described in detail in this specification are within the skill of the art.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. The utility model provides a robot protective clothing with temperature control function, includes installation base (1), outer inoxidizing coating (2), interior inoxidizing coating (5) and cold wind air-supply line (12), its characterized in that: the outer protective layer (2) is installed at the upper end of the installation base (1) in a nested mode, a sealing gasket (3) is installed on the upper end face of the installation base (1) through a bolt, the sealing gasket (3) is connected with the lower end of the outer protective layer (2), the outer side of the installation base (1) is provided with an air outlet pipe (4) in a penetrating mode, the tail end of the air outlet pipe (4) is communicated with the inner side of the outer protective layer (2), the inner side of the outer protective layer (2) is connected with a supporting block (8) in a bonding mode, the lower end of the supporting block (8) is fixedly connected with an inner protective layer (5), the inner protective layer (5) is connected with the outer protective layer (2), an air vent (6) is formed in the outer end surface of the inner protective layer (5), a circulating channel (7) is formed between the inner protective layer (5) and, the outer side of outer inoxidizing coating (2) is run through and is installed cold wind air-supply line (12), and cold wind air-supply line (12) and circulation channel (7) switch on mutually, the internal surface bonding of cold wind air-supply line (12) is connected with thermostatic layer (10), and the external fixed surface on thermostatic layer (10) is connected with lug (11) to lug (11) are connected with the internal surface of cold wind air-supply line (12).

2. The robot protective clothing with the temperature control function according to claim 1, wherein: the outer protective layer (2) is provided with a limiting groove (201) and a fireproof layer (202), the limiting groove (201) is formed in the inner side of the outer protective layer (2), and the fireproof layer (202) is embedded and installed on the outer side of the limiting groove (201).

3. The robot protective clothing with the temperature control function according to claim 2, wherein: the fireproof layer (202) is made of glass wool, the outer surface of the fireproof layer (202) is in a concave-convex structure, and the fireproof layer (202) is in concave-convex fit with the inner side of the outer protective layer (2) through the limiting groove (201).

4. The robot protective clothing with the temperature control function according to claim 1, wherein: the inner protective layer (5) is of a ring-shaped structure, the inner protective layer (5) is made of hydrophobic coating materials, and the inner side of the inner protective layer (5) and the inner side of the outer protective layer (2) form a nested structure.

5. The robot protective clothing with the temperature control function according to claim 1, wherein: the supporting blocks (8) are made of elastic rubber, 3 supporting blocks (8) are arranged at equal intervals relative to the central point of the inner protective layer (5), and the inner protective layer (5) and the inner side of the outer protective layer (2) form an elastic structure through the supporting blocks (8).

6. The robot protective clothing with the temperature control function according to claim 1, wherein: the cold air inlet pipe (12) is of an L-shaped structure in front view, and the cold air inlet pipe (12) and the constant temperature layer (10) form a clamping structure through the bump (11).

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