CN216733606U - Heat exchange device for rapid heat dissipation of printer system - Google Patents

Abstract

The utility model relates to the technical field of printers, in particular to a heat exchange device for quickly radiating a printer system, which comprises a heat transfer mechanism, a radiating mechanism, a driving pump and a pipeline, wherein the heat transfer mechanism comprises a heat transfer plate, a heat exchange agent inlet pipe, a heat exchange agent outlet pipe, a transverse flow channel pipe and a longitudinal flow channel pipe; through setting up heat transfer mechanism, heat dissipation mechanism and actuating pump, solved and generally put indoor in the printer at present, and probably need not incessantly print in succession according to the work demand, if the radiating effect is poor, influence printer work smoothness nature on the one hand, also can influence the problem of printing the effect on the one hand.

Description

Heat exchange device for rapid heat dissipation of printer system

Technical Field

The utility model relates to the technical field of printers, in particular to a heat exchange device for quickly radiating heat of a printer system.

Background

The printer is generally similar to a computer device, because the printer is an electronic product and an electric product, a fan is generally used for air cooling heat dissipation in consideration of the use safety of electric elements, but the cooling efficiency of the air cooling heat dissipation is the lowest among various heat exchange modes, and the cooling effect is the worst.

At present, the printer is generally placed indoors, continuous printing is possibly required according to working requirements, if the heat dissipation effect is poor, the working smoothness of the printer is influenced on the one hand, and the printing effect is also influenced on the other hand, so that the problem is improved by the heat exchange device for quickly dissipating heat of the printer system.

SUMMERY OF THE UTILITY MODEL

The present invention is directed to a heat exchange device for quickly dissipating heat of a printer system, so as to solve the problems mentioned in the background art.

In order to achieve the purpose, the utility model provides the following technical scheme:

the utility model provides a heat exchange device for quick radiating of printer system, includes heat transfer mechanism, heat dissipation mechanism, driving pump and pipeline, heat transfer mechanism includes heat transfer plate, heat transfer agent admission pipe, heat transfer agent outlet pipe, horizontal runner pipe and vertical runner pipe, heat dissipation mechanism includes heating panel, high temperature heat transfer agent admission pipe, low temperature heat transfer agent outlet pipe, horizontal cooling tube, vertical cooling tube and radiating fin, heat transfer mechanism installs in printer work portion position department, heat dissipation mechanism installs in printer non-work portion position department, all be connected through the pipeline between heat transfer mechanism, driving pump and the heat dissipation mechanism.

As a preferable scheme of the utility model, the heat transfer plate is arranged in the printer, the top of the heat transfer plate is provided with the heat exchange agent inlet pipe, the bottom of the heat transfer plate is provided with the heat exchange agent outlet pipe, the bottom of the heat exchange agent inlet pipe and the top of the heat exchange agent outlet pipe are both provided with the transverse flow channel pipe, and the outer wall of the transverse flow channel pipe is provided with the longitudinal flow channel pipe.

As a preferable scheme of the present invention, the heat dissipating plate is installed in the printer, the top of the heat dissipating plate is installed with the high temperature heat transfer agent inlet pipe, the bottom of the heat dissipating plate is installed with the low temperature heat transfer agent outlet pipe, the bottom of the high temperature heat transfer agent inlet pipe and the top of the low temperature heat transfer agent outlet pipe are both installed with the transverse heat dissipating pipe, the outer wall of the transverse heat dissipating pipe is installed with the longitudinal heat dissipating pipe, and the front surface of the heat dissipating plate is installed with the heat dissipating fins.

As the preferred scheme of the utility model, heat exchange agents are packaged in the heat transfer mechanism, the heat dissipation mechanism, the driving pump and the pipeline, the driving pump is provided with a one-way electromagnetic valve, and the heat dissipation mechanism is arranged above the heat transfer mechanism.

The heat transfer plates are provided with a plurality of groups, the heat transfer plates are connected together in parallel through the guide pipes, the longitudinal flow channel pipes are provided with a plurality of groups, the longitudinal flow channel pipes are respectively arranged in the heat transfer plates, and the heat transfer plates are made of flat copper plates.

As a preferable scheme of the utility model, the heat dissipation plates are provided with a plurality of groups, the plurality of groups of heat dissipation plates are connected together in parallel through the guide pipe, the plurality of groups of longitudinal heat dissipation tubes are arranged in the heat dissipation plates respectively, the longitudinal heat dissipation tubes are designed into a wave-shaped mechanism, the high-temperature heat exchange agent inlet tube and the low-temperature heat exchange agent outlet tube are provided with a plurality of groups, the high-temperature heat exchange agent inlet tube and the low-temperature heat exchange agent outlet tube are arranged in a staggered mode, the plurality of groups of heat dissipation fins are arranged, and obvious gaps are reserved among the plurality of groups of heat dissipation fins.

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

(1) in the utility model, by arranging the heat transfer mechanism, the heat dissipation mechanism and the driving pump, the low-temperature heat exchange agent in the heat dissipation mechanism slowly flows into the heat transfer plate under the action of gravity, fully contacts with the heating device and absorbs heat, the heat exchange agent absorbing the heat flows into the driving pump, when the flow of the heat exchange agent flowing into the driving pump in the forward direction reaches a certain value, the electromagnetic valve in the driving pump is opened, the heat exchange agent is sent into the heat dissipation part by the driving pump, the high-temperature heat exchange agent is intensively dissipated in the heat dissipation plate and is changed back to the low-temperature heat exchange agent again, the fan cooling mode can be adopted, the heat exchange efficiency is improved, the heat exchange agent is packaged in the metal tube, the plate and the shell, the heat exchange agent can be recycled infinitely, the leakage probability is very small, the heat exchange agent uses non-toxic, tasteless and non-volatile liquid substances, the metal cannot be corroded, even if the leakage does not cause damage to electronic devices and human bodies, the problem that the printer is generally placed indoors at present is solved, and perhaps need print incessantly in succession according to the work demand, if the radiating effect is poor, influence printer work smoothness nature on the one hand, also can influence the problem of printing the effect on the one hand.

(2) According to the utility model, by arranging the heat transfer mechanism and the heat dissipation mechanism, the transverse flow channel pipe can flow the heat transfer agent uniformly, the heat transfer agent is prevented from flowing out of the heat transfer plate quickly through the shortcut channel, the heat dissipation fins increase the outer surface area of the heat dissipation plate, so that the convection heat transfer area is increased, obvious gaps are left among different groups of heat dissipation fins, space is provided for natural wind flowing, the natural convection heat transfer effect is improved, the longitudinal heat dissipation pipe is designed by adopting a wave-shaped mechanism, the heat transfer area can be increased, the heat transfer effect is improved, the high-temperature heat transfer agent inlet pipe and the low-temperature heat transfer agent outlet pipe are arranged in a staggered mode as much as possible, the heat transfer agent is prevented from flowing through the shortcut channel in the heat dissipation plate, the heat transfer system is smooth in surface except the fins, the heat transfer system is convenient to clean, meanwhile, the fins are generally positioned outside, and can be cleaned by using a conventional method.

Drawings

FIG. 1 is a schematic diagram of a heat exchange cycle according to the present invention;

FIG. 2 is a schematic view of a heat transfer plate according to the present invention;

fig. 3 is a schematic view of the heat dissipation plate structure of the present invention.

In the figure:

1. a heat transfer mechanism;

101. a heat transfer plate; 102. a heat transfer agent inlet pipe; 103. a heat exchange agent outflow pipe; 104. a transverse flow channel tube; 105. a longitudinal runner tube;

2. a heat dissipation mechanism;

201. a heat dissipation plate; 202. the high-temperature heat exchange agent enters the pipe; 203. a low-temperature heat exchange agent outflow pipe; 204. a transverse radiating pipe; 205. a longitudinal radiating pipe; 206. a heat dissipating fin;

3. driving the pump;

4. a pipeline.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, rather than all of the embodiments, and based on the embodiments of the present invention, all other embodiments obtained by a person skilled in the art without making creative efforts belong to the protection scope of the present invention.

While several embodiments of the present invention will be described more fully hereinafter with reference to the accompanying drawings, in order to facilitate an understanding of the utility model, the utility model may be embodied in many different forms and should not be construed as limited to the embodiments set forth herein, but rather should be construed to provide a more complete disclosure of the utility model.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present, that when an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present, and that the terms "vertical", "horizontal", "left", "right" and the like are used herein for descriptive purposes only.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs, and the terms used herein in the specification of the present invention are for the purpose of describing particular embodiments only and are not intended to limit the present invention, and the term "and/or" as used herein includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1-3, the present invention provides a technical solution:

a heat exchange device for rapid heat dissipation of a printer system comprises a heat transfer mechanism 1, a heat dissipation mechanism 2, a driving pump 3 and a pipeline 4, wherein the heat transfer mechanism 1 comprises a heat transfer plate 101, a heat exchange agent inlet pipe 102, a heat exchange agent outlet pipe 103, a transverse flow passage pipe 104 and a longitudinal flow passage pipe 105, the heat dissipation mechanism 2 comprises a heat dissipation plate 201 and a high-temperature heat exchange agent inlet pipe 202, the low-temperature heat exchange agent outlet pipe 203, the transverse radiating pipe 204, the longitudinal radiating pipe 205 and the radiating fins 206, the heat transfer mechanism 1 is installed at the position of a working part of the printer, the radiating mechanism 2 is installed at the position of a non-working part of the printer, the heat transfer mechanism 1, the driving pump 3 and the radiating mechanism 2 are connected through the pipeline 4, the heat exchange agent is packaged in the heat transfer mechanism 1, the radiating mechanism 2, the driving pump 3 and the pipeline 4, the driving pump 3 is provided with a one-way electromagnetic valve, and the radiating mechanism 2 is installed above the heat transfer mechanism 1.

In an embodiment, referring to fig. 1 and 2, a heat transfer plate 101 is installed in a printer, a heat exchange agent inlet tube 102 is installed at the top of the heat transfer plate 101, a heat exchange agent outlet tube 103 is installed at the bottom of the heat transfer plate 101, transverse flow channel tubes 104 are installed at the bottom of the heat exchange agent inlet tube 102 and the top of the heat exchange agent outlet tube 103, longitudinal flow channel tubes 105 are installed on the outer wall of the transverse flow channel tubes 104, a plurality of groups of heat transfer plates 101 are provided, the plurality of groups of heat transfer plates 101 are connected in parallel through a guide tube, the plurality of groups of longitudinal flow channel tubes 105 are provided, the plurality of groups of longitudinal flow channel tubes 105 are respectively arranged in the heat transfer plates 101, and the heat transfer plates 101 are made of flat copper plates.

The low-temperature heat exchange agent in the heat dissipation mechanism 2 slowly flows into the heat transfer plate 101 under the action of gravity, fully contacts with the heating device and absorbs heat, the heat-absorbed heat exchange agent flows into the driving pump 3, when the flow of the heat exchange agent flowing into the driving pump 3 in the forward direction reaches a certain value, the electromagnetic valve in the driving pump 3 is opened, the driving pump 3 sends the heat exchange agent into the heat dissipation plate 201, the high-temperature heat exchange agent performs centralized heat dissipation in the heat dissipation plate 201 and is changed back to the low-temperature heat exchange agent again, the transverse flow channel pipe 104 can flow the heat exchange agent uniformly, and the heat exchange agent is prevented from flowing out of the heat transfer plate 101 through the shortcut channel quickly.

Example, referring to fig. 1 and 3, a heat dissipating plate 201 is installed in a printer, a high temperature heat transfer agent inlet pipe 202 is installed on the top of the heat dissipating plate 201, a low temperature heat transfer agent outlet pipe 203 is installed on the bottom of the heat dissipating plate 201, horizontal heat dissipating pipes 204 are installed on the bottom of the high temperature heat transfer agent inlet pipe 202 and the top of the low temperature heat transfer agent outlet pipe 203, longitudinal heat dissipating pipes 205 are installed on the outer walls of the horizontal heat dissipating pipes 204, heat dissipating fins 206 are installed on the front surface of the heat dissipating plate 201, the heat dissipating plate 201 is provided with a plurality of sets, the heat dissipating plates 201 are connected together in parallel through pipes, the longitudinal heat dissipating pipes 205 are provided with a plurality of sets, the longitudinal heat dissipating pipes 205 are respectively arranged in the heat dissipating plate 201, the longitudinal heat dissipating pipes 205 are designed as a wave-shaped mechanism, the high temperature heat transfer agent inlet pipe 202 and the low temperature heat transfer agent outlet pipe 203 are provided with a plurality of sets, and the high temperature heat transfer agent inlet pipe 202 and the low temperature heat transfer agent outlet pipe 203 are arranged in a staggered manner, the plurality of sets of fins 206 are provided, and a significant gap is left between the plurality of sets of fins 206.

Radiating fin 206 increases the surface area of heating panel 201, thereby increase the heat transfer area of convection, leave obvious space between different group radiating fin 206, flow for the natural wind and provide the space, improve the natural heat transfer effect of convection, vertical cooling tube 205 adopts the design of wave mechanism, can increase the area that can the heat transfer, improve the heat transfer effect, high temperature heat transfer agent admission pipe 202 and low temperature heat transfer agent outflow pipe 203 stagger the arrangement as far as possible, avoid the heat transfer agent to walk the shortcut runner in heating panel 201.

The working process of the utility model is as follows: the low-temperature heat exchange agent in the heat dissipation mechanism 2 slowly flows into the heat transfer plate 101 under the action of gravity, fully contacts with the heating device and absorbs heat, the heat-absorbed heat exchange agent flows into the driving pump 3, when the flow rate of the heat exchange agent flowing into the driving pump 3 in the forward direction reaches a certain value, the electromagnetic valve in the driving pump 3 is opened, the driving pump 3 sends the heat exchange agent into the heat dissipation plate 201, and the high-temperature heat exchange agent is intensively dissipated in the heat dissipation plate 201 and is changed back to the low-temperature heat exchange agent again.

The transverse flow channel pipe 104 can flow heat transfer agent evenly, avoid the heat transfer agent to flow out of the heat transfer plate 101 through the shortcut channel quickly, the radiating fins 206 increase the outer surface area of the radiating plate 201, thereby increasing the heat convection area, obvious gaps are left between the radiating fins 206 of different groups, provide space for natural wind flow, improve the natural heat convection effect, the longitudinal radiating pipe 205 adopts the wave-shaped mechanism design, the area capable of exchanging heat can be increased, the heat exchange effect is improved, the high-temperature heat transfer agent inlet pipe 202 and the low-temperature heat transfer agent outlet pipe 203 are arranged in a staggered mode as much as possible, and the heat transfer agent is prevented from flowing through the shortcut channel in the radiating plate 201.

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 utility model, the scope of which is defined in the appended claims and their equivalents.

Claims (6)

1. A heat exchange device for quick heat dissipation of a printer system comprises a heat transfer mechanism (1), a heat dissipation mechanism (2), a driving pump (3) and a pipeline (4), and is characterized in that: heat transfer mechanism (1) includes heat transfer plate (101), heat transfer agent admission pipe (102), heat transfer agent outlet pipe (103), horizontal runner pipe (104) and vertical runner pipe (105), heat dissipation mechanism (2) are including heating panel (201), high temperature heat transfer agent admission pipe (202), low temperature heat transfer agent outlet pipe (203), horizontal cooling tube (204), vertical cooling tube (205) and radiating fin (206), heat transfer mechanism (1) is installed in printer work portion position department, install in printer non-work portion position department in heat dissipation mechanism (2), all be connected through pipeline (4) between heat transfer mechanism (1), driving pump (3) and heat dissipation mechanism (2).

2. The heat exchange device for rapid heat dissipation in a printer system of claim 1, wherein: the printer is characterized in that the heat transfer plate (101) is installed in the printer, a heat exchange agent inlet pipe (102) is installed at the top of the heat transfer plate (101), a heat exchange agent outlet pipe (103) is installed at the bottom of the heat transfer plate (101), transverse flow channel pipes (104) are installed at the bottom of the heat exchange agent inlet pipe (102) and the top of the heat exchange agent outlet pipe (103), and longitudinal flow channel pipes (105) are installed on the outer wall of the transverse flow channel pipes (104).

3. The heat exchanging apparatus for rapid heat dissipation of a printer system as recited in claim 1, wherein: heating panel (201) are installed in the printer, high temperature heat transfer agent admission pipe (202) are installed at the top of heating panel (201), low temperature heat transfer agent outlet pipe (203) is installed to the bottom of heating panel (201), horizontal cooling tube (204) are all installed to the bottom of high temperature heat transfer agent admission pipe (202) and the top of low temperature heat transfer agent outlet pipe (203), vertical cooling tube (205) are installed to the outer wall of horizontal cooling tube (204), radiating fin (206) are installed in the front of heating panel (201).

4. The heat exchange device for rapid heat dissipation in a printer system of claim 1, wherein: the heat transfer mechanism (1), the heat dissipation mechanism (2), the driving pump (3) and the pipeline (4) are internally provided with heat exchange agents in an encapsulated mode, the driving pump (3) is provided with a one-way electromagnetic valve, and the heat dissipation mechanism (2) is installed above the heat transfer mechanism (1).

5. The heat exchange device for rapid heat dissipation in a printer system of claim 1, wherein: the heat transfer plates (101) are provided with a plurality of groups, the heat transfer plates (101) are connected together in parallel through guide pipes, the longitudinal flow channel pipes (105) are provided with a plurality of groups, the longitudinal flow channel pipes (105) are respectively arranged in the heat transfer plates (101), and the heat transfer plates (101) are made of flat copper plates.

6. The heat exchange device for rapid heat dissipation in a printer system of claim 1, wherein: heating panel (201) are provided with the multiunit, and multiunit heating panel (201) are in the same place through pipe parallel connection, vertical cooling tube (205) are provided with the multiunit, and the vertical cooling tube of multiunit (205) by respectively in heating panel (201), vertical cooling tube (205) are the design of wave mechanism, high temperature heat transfer agent admission pipe (202) and low temperature heat transfer agent outlet pipe (203) all are provided with the multiunit, and high temperature heat transfer agent admission pipe (202) and low temperature heat transfer agent outlet pipe (203) arrange for staggering, radiating fin (206) are provided with the multiunit, and leave obvious space between multiunit radiating fin (206).

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