CN221043611U - Terminal data acquisition device based on communication unit - Google Patents

Abstract

The utility model discloses a terminal data acquisition device based on a communication unit, which relates to the technical field of communication equipment, and is technically characterized in that: the system comprises a terminal data acquisition host; the heat dissipation structure is arranged at the outer side of the terminal data acquisition host and is used for providing an efficient cooling and heat dissipation effect for the inside of the terminal data acquisition host; the circulating structure is arranged at one end of the heat dissipation structure and is used for communicating the inside of the terminal data acquisition host and the inside of the heat dissipation structure and circularly cooling the air flow; the air inlet structure is arranged in the heat radiation structure and used for cooling and radiating air in the circulation structure and the terminal data acquisition host, and has the effects that the refrigerating end of the semiconductor refrigerator is arranged in the refrigerating room and is communicated with the terminal data acquisition host through the exhaust fan, the cold air pipe and the cold air port, cold air generated by the semiconductor refrigerator is blown into the terminal data acquisition host, hot air in the terminal data acquisition host is outwards extracted through the heat radiation fan, and high-efficiency heat radiation protection is provided.

Description

Terminal data acquisition device based on communication unit

Technical Field

The utility model relates to the technical field of communication equipment, in particular to a terminal data acquisition device based on a communication unit.

Background

The communication control unit is a device in the computer network responsible for communication between the host and the terminal, and controls all communication channels connected with the remote data device to realize functions including error control, interrupt access control, acknowledgement control, transmission sequence, serial-parallel conversion and the like. The communication control unit reduces the load of the host computer and greatly improves the efficiency of processing data by the host computer.

The data acquisition refers to automatically acquiring non-electric quantity or electric quantity signals from analog and digital measured units of a sensor, other equipment to be measured and the like, and sending the signals to an upper computer for analysis and processing. The data acquisition system is a flexible and user-defined measurement system realized by combining measurement software and hardware products based on a computer or other special test platforms, so that the development of communication technology is accelerated by the terminal data acquisition device based on the communication unit.

The existing terminal data acquisition device on the market generally can give off a large amount of heat in the use, especially communication unit, because the inside data transceiver of communication unit handles more, consequently the terminal data acquisition device work based on communication unit is more, can outwards give off a large amount of heat in the host computer, and the inside heat dissipation of current host computer generally relies on the fan to dispel the heat, and the radiating effect is relatively poor, consequently needs an efficient heat abstractor to dispel the heat in the terminal data acquisition host computer of communication unit to guarantee the stability and the safety of data acquisition host computer operation.

Therefore, in order to solve the technical problems, the application provides a terminal data acquisition device based on a communication unit.

Disclosure of utility model

Aiming at the defects existing in the prior art, the utility model aims to provide a terminal data acquisition device based on a communication unit.

In order to achieve the above purpose, the present utility model provides the following technical solutions: comprising the following steps:

A terminal data acquisition host;

The heat dissipation structure is arranged at the outer side of the terminal data acquisition host and is used for providing an efficient cooling and heat dissipation effect for the inside of the terminal data acquisition host;

the circulating structure is arranged at one end of the heat dissipation structure and is used for communicating the inside of the terminal data acquisition host and the inside of the heat dissipation structure and circularly cooling the air flow;

the air inlet structure is arranged in the heat dissipation structure and is used for cooling and dissipating heat by air inlet in the circulating structure and the terminal data acquisition host;

The terminal data acquisition host computer one side fixed mounting has heat radiation structure, outwards take out through the steam in the terminal data acquisition host computer in the heat radiation structure, blow the air conditioning that produces in the heat radiation structure in the terminal data acquisition host computer simultaneously to cool down and dispel the heat in the terminal data acquisition host computer, one end installation inlet structure and intercommunication circulating structure in the heat radiation structure, be used for in the inlet structure intercommunication circulating structure to cool down in advance through circulating structure to the inhaled air after discharging to the heat radiation structure in further cooling down, thereby realize carrying out more efficient cooling heat dissipation in the terminal data acquisition host computer.

Preferably, the heat dissipation structure comprises a heat dissipation box, an exhaust fan, a refrigerating chamber, a cold air pipe, a semiconductor refrigerator, a heat dissipation chamber, a heat dissipation pipe, a heat dissipation fan and a cold air port, wherein the heat dissipation box is fixedly arranged at the outer side of one end of the terminal data acquisition host, the heat dissipation chamber and the refrigerating chamber which are mutually independent and separated are arranged in the heat dissipation box in an up-down structure, the semiconductor refrigerator is installed in the heat dissipation chamber in a matched manner, the refrigerating end of the semiconductor refrigerator is installed in the refrigerating chamber, the heat dissipation end of the semiconductor refrigerator is installed in the heat dissipation chamber, the heat dissipation pipe is fixedly installed at the top of one side of the heat dissipation chamber, which is close to the terminal data acquisition host, the bottom of the heat dissipation pipe is communicated with the inner top of the terminal data acquisition host through the heat dissipation fan, the exhaust fan is fixedly installed at the bottom of the refrigerating chamber, the bottom of the exhaust fan is communicated with the cold air pipe inserted at the inner bottom of the terminal data acquisition host, and the cold air port used for blowing in the terminal data acquisition host is connected to the surface of the cold air pipe;

The cooling end of the semiconductor refrigerator is arranged in the cooling chamber and is communicated with the terminal data acquisition host through the exhaust fan, the cold air pipe and the cold air port, so that cold air generated by the semiconductor refrigerator is blown into the terminal data acquisition host, and meanwhile, hot air in the terminal data acquisition host is outwards extracted through the cooling fan, so that efficient heat dissipation protection is provided for the terminal data acquisition host.

Preferably, the air inlet structure comprises filter cotton, an air inlet box, fixing plates, inserting rods, a fish plate, spring rods, inserting blocks, a filter bin and a limiting groove, wherein the air inlet box is fixedly arranged at the top of one end of a radiating pipe far away from a discrete hot box, the filter bin for installing the filter cotton is arranged in the air inlet box, the inserting blocks are fixedly arranged at the outer sides of two ends of the air inlet box, the inserting rods are detachably inserted in the inserting blocks, the fixing plates are fixedly connected with the top ends of the inserting rods, the fixing plates are fixedly arranged at the two ends of the top of the filter cotton, the limiting plates are fixedly arranged at the outer sides of the inserting rods, the limiting plates are detachably inserted in the limiting grooves, the limiting grooves are correspondingly formed in one side, far away from the air inlet box, the spring rods are slidably inserted in the limiting grooves, and the bottoms in the air inlet box are communicated with the air inlet chamber;

Through at cooling tube top installation box and can dismantle grafting filter pulp, peg graft the filter pulp through inserted bar and limiting plate in the spacing inslot in the inserted block to fix the filter pulp, thereby filter the inside air current of entering terminal data acquisition host computer, effectively prevent in the dust entering terminal data acquisition host computer in the outside air.

Preferably, the circulating structure comprises a circulating chamber, a spiral condensing pipe, an inner pipe, an air inlet chamber, a cold air port, an air pipe and an air supplementing port, wherein the inner pipe is fixedly inserted into one side of the air inlet chamber, the inner pipe is fixedly communicated with the spiral condensing pipe, the inner bottom end of the spiral condensing pipe is fixedly connected with one end of the air pipe, the air pipe is fixedly inserted into the inner bottom of a terminal data acquisition host, the other end of the air pipe is inserted into the bottom of the refrigerating chamber, the spiral condensing pipe is fixedly installed in the circulating chamber, the cold air port is fixedly installed at the bottom of the circulating chamber, and the cold air port is fixedly communicated with the bottom end of the cold air pipe;

Through set up the circulation room and install spiral condenser pipe in terminal data acquisition host computer one side, with spiral condenser pipe top intercommunication inner tube and peg graft in the air inlet room, link the breather pipe with spiral condenser pipe bottom and peg graft in the refrigeration room to with the cold gas port of cold tuber pipe is connected in the installation of circulation room, thereby cool down in advance the back to the inhaled air through the spiral condenser pipe and discharge and cool down after cooling again in the refrigeration room, thereby realize cooling heat dissipation in the terminal data acquisition host computer.

Preferably, a protective cover for providing rainproof protection is fixedly arranged on the outer side of the radiating chamber;

and the position of the air outlet at the outer side of the radiating chamber is provided with rainproof protection through the protective cover.

Preferably, a dust-proof fish plate is fixedly arranged at the inner top of the air inlet box;

dust protection is provided in the air inlet box through the fish scale.

Compared with the prior art, the utility model has the following beneficial effects:

1. The cooling end of the semiconductor refrigerator is arranged in the cooling chamber and is communicated with the inside of the terminal data acquisition host through the exhaust fan, the cold air pipe and the cold air port, so that cold air generated by the semiconductor refrigerator is blown into the terminal data acquisition host, and meanwhile, hot air in the terminal data acquisition host is outwards extracted through the cooling fan, so that efficient heat dissipation protection is provided for the inside of the terminal data acquisition host;

2. Through installing the air inlet box at the top of the radiating pipe and detachably inserting the filter cotton, inserting the filter cotton into the limit groove in the insert block through the insert rod and the limit plate, thereby fixing the filter cotton, filtering the air flow entering the terminal data acquisition host, and effectively preventing dust in the outside air from entering the terminal data acquisition host;

3. Through set up the circulation room and install spiral condenser pipe in terminal data acquisition host computer one side, with spiral condenser pipe top intercommunication inner tube and peg graft in the air inlet room, link the breather pipe with spiral condenser pipe bottom and peg graft in the refrigeration room to with the cold gas port of cold tuber pipe is connected in the installation of circulation room, thereby cool down in advance the back to the inhaled air through the spiral condenser pipe and discharge and cool down after cooling again in the refrigeration room, thereby realize cooling heat dissipation in the terminal data acquisition host computer.

Drawings

The accompanying drawings, which are included to provide a further understanding of the utility model and are incorporated in and constitute a part of this specification, illustrate embodiments of the utility model and together with the description serve to explain the utility model and do not constitute a limitation on the utility model. In the drawings:

FIG. 1 is a schematic view of the overall structure of the present utility model;

FIG. 2 is a schematic view of the structure of the cold air duct of the present utility model;

FIG. 3 is an enlarged view of the utility model at A in FIG. 1;

Fig. 4 is an enlarged view of fig. 3 at B in accordance with the present utility model.

1-A terminal data acquisition host; 2-a heat dissipation structure; 201-a heat dissipation box; 202-an exhaust fan; 203-a refrigeration chamber; 204, a cold air pipe; 205-semiconductor refrigerator; 206-a heat dissipation chamber; 207-radiating pipes; 208-a heat dissipation fan; 209-cooling tuyere; 3-cycle structure; 301-a circulation chamber; 302-a spiral condenser tube; 303-inner tube; 304-an inlet chamber; 305-cold air ports; 306-trachea; 307-make-up port; 4-an air intake structure; 401-filtering cotton; 402-an air inlet box; 403-a fixed plate; 404-inserting a rod; 405-fish scale; 406-spring bar; 407-plug-in block; 408-a filtration bin; 409-limit groove; 410-limiting plates; 5-protective cover.

Detailed Description

As shown in fig. 1 to 4, the present utility model provides a terminal data acquisition device based on a communication unit, including:

A terminal data acquisition host 1;

The heat dissipation structure 2 is arranged at the outer side of the terminal data acquisition host 1 and is used for providing an efficient cooling and heat dissipation effect for the inside of the terminal data acquisition host 1;

The circulating structure 3 is arranged at one end of the heat dissipation structure 2 and is used for communicating the inside of the terminal data acquisition host 1 and the inside of the heat dissipation structure 2 and circularly cooling the air flow;

The air inlet structure 4 is arranged in the heat dissipation structure 2 and is used for carrying out cooling and heat dissipation on air inlet in the circulation structure 3 and the terminal data acquisition host 1;

A heat radiation structure 2 is fixedly arranged on one side of the terminal data acquisition host 1, hot air in the terminal data acquisition host 1 is outwards pumped out in the heat radiation structure 2, and meanwhile cool air generated in the heat radiation structure 2 is blown into the terminal data acquisition host 1, so that the terminal data acquisition host 1 is cooled and radiated, one end in the heat radiation structure 2 is provided with an air inlet structure 4 and communicated with a circulating structure 3, the air inlet structure 4 is communicated with the circulating structure 3 and is used for carrying out pre-cooling and heat radiation on sucked air through the circulating structure 3 and then discharging the air into the heat radiation structure 2 for further cooling, and therefore more efficient cooling and heat radiation on the terminal data acquisition host 1 are realized;

The heat radiation structure 2 comprises a heat radiation box 201, an exhaust fan 202, a refrigerating chamber 203, a cold air pipe 204, a semiconductor refrigerator 205, a heat radiation chamber 206, a heat radiation pipe 207, a heat radiation fan 208 and a cold air port 209, wherein the heat radiation box 201 is fixedly arranged at the outer side of one end of the terminal data acquisition host 1, the heat radiation chamber 206 and the refrigerating chamber 203 which are mutually independent and separated are arranged in the heat radiation box 201 in an up-down structure, the semiconductor refrigerator 205 is arranged in the heat radiation chamber 206 and the refrigerating chamber 203 in a matched manner, the refrigerating end of the semiconductor refrigerator 205 is arranged in the refrigerating chamber 203, the heat radiation end of the semiconductor refrigerator 205 is arranged in the heat radiation chamber 206, the heat radiation pipe 207 is fixedly arranged at the top of one side of the heat radiation chamber 206, which is close to the terminal data acquisition host 1, the bottom of the heat radiation pipe 207 is communicated with the inner top of the terminal data acquisition host 1 through the heat radiation fan 208, the exhaust fan 202 is fixedly arranged at the bottom of the heat radiation chamber 203, the cold air pipe 204 is communicated with the bottom of the terminal data acquisition host 1, and the cold air port 209 for blowing cold air into the terminal data acquisition host 1 is connected to the surface of the cold air pipe 204;

When the terminal data acquisition host 1 is cooled and radiated, a semiconductor refrigerator 205, an exhaust fan 202, a radiator fan 208 and the like are started, the semiconductor refrigerator 205 is started in a refrigerating chamber 203 to perform refrigeration and radiation, meanwhile, hot air released in a radiator chamber 206 is discharged outwards, cold air in the refrigerating chamber 203 is pumped into a cold air pipe 204 through the exhaust fan 202 and blown into the terminal data acquisition host 1 through a cold air port 209, and hot air is pumped outwards through the radiator fan 208 at the top of the terminal data acquisition host 1, so that the hot air is discharged outwards through the radiator chamber 206 through a radiator pipe 207, and the efficient cooling and radiation of the terminal data acquisition host 1 is improved;

the circulating structure 3 comprises a circulating chamber 301, a spiral condensing pipe 302, an inner pipe 303, an air inlet chamber 304, a cold air port 305, an air pipe 306 and an air supplementing port 307, wherein the inner pipe 303 is fixedly inserted into one side of the air inlet chamber 304, the inner pipe 303 is fixedly communicated with the inside of the spiral condensing pipe 302, the inner bottom end of the spiral condensing pipe 302 is fixedly connected with one end of the air pipe 306, the air pipe 306 is fixedly inserted into the inner bottom of the terminal data acquisition host 1, the other end of the air pipe 306 is inserted into the inner bottom of the refrigerating chamber 203, the spiral condensing pipe 302 is fixedly arranged in the circulating chamber 301, the cold air port 305 is fixedly arranged at the inner bottom of the circulating chamber 301, and the cold air port 305 is fixedly communicated with the bottom end of the cold air pipe 204;

While cooling and radiating, the air inlet box 402 pumps outside air inwards, firstly, the sucked air is filtered through the filter cotton 401, so that the air is conveyed into the refrigerating chamber 203 through the air pipe 306 after passing through the spiral condensing pipe 302 through the inner pipe 303 for cooling in advance, part of cold air is blown into the circulating chamber 301 through the cold air pipe 204 and the cold air port 305 in the refrigerating chamber 203, thereby cooling condensate in the spiral condensing pipe 302, cooling and radiating the sucked air through the condensate, and further cooling the sucked air in the refrigerating chamber 203 after cooling in advance, thereby realizing cooling and radiating use in the terminal data acquisition host 1;

The air inlet structure 4 comprises filter cotton 401, an air inlet box 402, fixing plates 403, inserting rods 404, a louver 405, spring rods 406, inserting blocks 407, a filter bin 408 and limiting grooves 409, wherein the air inlet box 402 is fixedly arranged at the top of one end, far away from the heat dissipation box 201, of each radiating pipe 207, the filter bin 408 for installing the filter cotton 401 is arranged in the air inlet box 402, inserting blocks 407 are fixedly arranged at the outer sides of two ends of the air inlet box 402, inserting rods 404 are detachably inserted in the inserting blocks 407, the fixing plates 403 are fixedly connected with the top ends of the inserting rods 404, the fixing plates 403 are fixedly arranged at the two ends of the top of the filter cotton 401, limiting plates 410 are fixedly arranged at the outer sides of the inserting rods 404, the limiting plates 410 are detachably inserted in the limiting grooves 409, the limiting grooves 409 are correspondingly arranged at one side, far away from the air inlet box 402, the spring rods 406 are slidably inserted in the limiting grooves 409, and the inner bottoms of the air inlet box 402 are communicated with the air inlet chamber 304;

After the filter cotton 401 is used for a period of time, the filter cotton 401 needs to be replaced, the spring rod 406 is pressed inwards to press the limiting plate 410, the limiting plate 410 is ejected outwards from the limiting groove 409, so that after the limiting plate 410 is separated from the limiting groove 409, the inserting rod 404 can be pulled out from the inserting block 407, after the filter cotton 401 is pulled out from the filter bin 408, the new filter cotton 401 is reinserted in the filter bin 408, the inserting rod 404 is correspondingly inserted in the inserting block 407, the limiting plate 410 is limited by the inner diameter of the inserting block 407, the limiting plate 410 is pressed inwards, and after the inserting rod 404 is completely inserted into the inserting block 407, the limiting plate 410 is outwards rebounded after being limited, and is inserted in the limiting groove 409, so that the filter cotton 401 is fixedly limited;

a protective cover 5 for providing rainproof protection is fixedly arranged outside the heat dissipation chamber 206;

the position of an air outlet outside the heat dissipation chamber 206 is provided with rainproof protection through the protective cover 5;

A dust-proof fish scale plate 405 is fixedly arranged at the inner top of the air inlet box 402;

Dust protection is provided in the air inlet box 402 by the louvers 405.

The above description is only of the preferred embodiments of the present utility model, and is not intended to limit the present utility model in any way; those skilled in the art will readily appreciate that the present utility model may be implemented as shown in the drawings and described above; however, those skilled in the art will appreciate that many modifications, adaptations, and variations of the present utility model are possible in light of the above teachings, without departing from the scope of the utility model; meanwhile, any equivalent changes, modifications and evolution of the above embodiments according to the essential technology of the present utility model still fall within the scope of the present utility model.

Claims (6)

1. The terminal data acquisition device based on the communication unit is characterized by comprising:

a terminal data acquisition host (1);

The heat dissipation structure (2) is arranged at the outer side of the terminal data acquisition host (1) and is used for providing an efficient cooling and heat dissipation effect for the inside of the terminal data acquisition host (1);

The circulating structure (3) is arranged at one end of the heat dissipation structure (2) and is used for communicating the inside of the terminal data acquisition host (1) and the inside of the heat dissipation structure (2) and circularly cooling the air flow;

The air inlet structure (4) is arranged in the heat dissipation structure (2) and is used for cooling and dissipating heat by air inlet in the circulation structure (3) and the terminal data acquisition host (1);

The terminal data acquisition host computer (1) one side fixed mounting has heat radiation structure (2), outwards take out through the steam in with terminal data acquisition host computer (1) in heat radiation structure (2), blow the air conditioning that produces in heat radiation structure (2) in terminal data acquisition host computer (1) simultaneously to cool down and dispel the heat in terminal data acquisition host computer (1), one end installation air inlet structure (4) and intercommunication circulation structure (3) in heat radiation structure (2), be used for in air inlet structure (4) intercommunication circulation structure (3) and carry out further cooling to heat radiation structure (2) in advance after cooling down to the inhaled air through circulation structure (3), thereby realize carrying out more efficient cooling and heat dissipation in terminal data acquisition host computer (1).

2. A terminal data acquisition device based on a communication unit according to claim 1, characterized in that: the heat radiation structure (2) comprises a heat radiation box (201), an exhaust fan (202), a refrigerating chamber (203), a cold air pipe (204), a semiconductor refrigerator (205), a heat radiation chamber (206), a heat radiation pipe (207), a heat radiation fan (208) and a cold air port (209), wherein the heat radiation box (201) is fixedly arranged at the outer side of one end of the terminal data acquisition host (1), the heat radiation chamber (206) and the refrigerating chamber (203) which are separated from each other in an up-down structure are arranged in the heat radiation box (201), the semiconductor refrigerator (205) is matched and installed in the refrigerating chamber (203), the refrigerating end of the semiconductor refrigerator (205) is installed in the refrigerating chamber (203), the heat radiation end of the semiconductor refrigerator (205) is installed in the heat radiation chamber (206), the heat radiation pipe (207) is fixedly installed at the top close to one side of the terminal data acquisition host (1) in the heat radiation chamber (206), the inner bottom of the heat radiation pipe (207) is communicated with the inner top of the terminal data acquisition host (1) through the heat radiation fan (208), the refrigerating end of the semiconductor refrigerator (205) is fixedly connected with the air exhaust fan (202) at the bottom of the air pipe (204), the surface of the cold air pipe (204) is connected with a cold air port (209) for blowing cold air into the terminal data acquisition host (1).

3. A terminal data acquisition device based on a communication unit according to claim 2, characterized in that: the utility model provides an inlet structure (4) is including filter pulp (401), inlet box (402), fixed plate (403), inserted bar (404), deck (405), spring beam (406), inserted bar (407), filtration storehouse (408) and spacing groove (409), cooling tube (207) are kept away from cooling box (201) one end top fixed mounting and are had inlet box (402), offer in inlet box (402) and be used for installing filter pulp (401) filtration storehouse (408), inlet box (402) both ends outside fixed mounting has inserted bar (407), detachable grafting has inserted bar (404) in inserted bar (407), inserted bar (404) top fixedly connected with fixed plate (403), fixed plate (403) fixed mounting is at filter pulp (401) top both ends, inserted bar (404) outside fixed mounting has limiting plate (410), limiting plate (410) are dismantled the grafting in spacing groove (409), limiting groove (409) are correspondingly offered in inserted bar (407) and are kept away from in inlet box (402) one side, interior sliding connection in inlet box (407) has inserted bar (406), inner bottom (304) intercommunication.

4. A terminal data acquisition device based on a communication unit according to claim 3, characterized in that: the circulating structure (3) comprises a circulating chamber (301), a spiral condensing pipe (302), an inner pipe (303), an air inlet chamber (304), an air cooling port (305), an air pipe (306) and an air supplementing port (307), wherein the inner pipe (303) is fixedly inserted into one side of the air inlet chamber (304), the inner pipe (303) is fixedly communicated with the spiral condensing pipe (302), one end of the air pipe (306) is fixedly connected with the inner bottom end of the spiral condensing pipe (302), the air pipe (306) is fixedly inserted into the inner bottom of a terminal data acquisition host (1), the other end of the air pipe (306) is inserted into the inner bottom of the refrigerating chamber (203), the spiral condensing pipe (302) is fixedly installed in the circulating chamber (301), the air cooling port (305) is fixedly installed in the inner bottom of the circulating chamber (301), and the air cooling port (305) is fixedly communicated with the bottom end of the air cooling pipe (204).

5. The communication unit-based terminal data acquisition device of claim 4, wherein: and a protective cover (5) for providing rainproof protection is fixedly arranged on the outer side of the radiating chamber (206).

6. The communication unit-based terminal data acquisition device of claim 5, wherein: a dust-proof fish scale plate (405) is fixedly arranged at the inner top of the air inlet box (402).