CN214841637U - Nano film-coated quartz heater - Google Patents

Abstract

The utility model discloses a nanometer tectorial membrane quartz heater, include: a liquid inlet and a liquid outlet are arranged in the flame-retardant shell; the heater is arranged in the flame-retardant shell and is provided with a liquid inlet pipe and a liquid outlet pipe, the liquid inlet pipe penetrates through the liquid inlet and extends to the outer side of the flame-retardant shell, and the liquid outlet pipe penetrates through the liquid outlet and extends to the outer side of the flame-retardant shell; the outer side wall of the heater is coated with a nano electrothermal film, and a heat-insulating layer is arranged between the flame-retardant shell and the heater; the liquid leakage sensor is fixed in the flame-retardant shell and is arranged right below the heater; the temperature sensor is fixedly connected with the heater, and the temperature sensor extends into the heater. Through heater surface coating nanometer electric heat membrane, reduce the power loss that heating power brought, keep warm to the heater through the heat preservation, simultaneously through temperature sensor and heater cooperation, reduce the heater and do not have the liquid phenomenon that dry combustion method leads to the heater to burn out to reduce the potential safety hazard that the burning out brought through fire-retardant shell.

Description

Nano film-coated quartz heater

Technical Field

The utility model relates to a heater field especially relates to a nanometer tectorial membrane quartz heater.

Background

At present, in the field of semiconductor heaters, a heater is arranged in the middle of a pipeline, and a heating wire is usually adopted to heat the heater, but the heating wire cannot be attached to the surface of the heater, so that the heating power loss is large, the thermal conductivity is low, and the heating speed is low.

Meanwhile, when the heater is dry-fired without liquid, the heater cannot be automatically powered off when the temperature is too high, so that the heater is burnt out, and potential safety hazards are brought.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to provide a can effectively solve above-mentioned technical problem's a nanometer tectorial membrane quartz heater.

In order to achieve the purpose of the utility model, the following technical proposal is adopted: a nano-coated quartz heater comprising:

the flame-retardant shell is internally provided with a liquid inlet and a liquid outlet;

the heater is arranged in the flame-retardant shell and is provided with a liquid inlet pipe and a liquid outlet pipe, the liquid inlet pipe penetrates through the liquid inlet and extends to the outer side of the flame-retardant shell, and the liquid outlet pipe penetrates through the liquid outlet and extends to the outer side of the flame-retardant shell; the outer side wall of the heater is coated with a nano electrothermal film, and a heat insulation layer is arranged between the flame-retardant shell and the heater;

the leakage inductor is fixed in the flame-retardant shell and is arranged right below the heater;

the temperature sensor is fixedly connected with the heater, and the temperature sensor extends into the heater.

Preferably, the flame-retardant shell is made of V2-grade fireproof plastic.

Preferably, the liquid inlet and the liquid outlet are respectively arranged at two sides of the flame-retardant shell, and the liquid inlet is lower than the liquid outlet.

Preferably, a liquid sensor is additionally arranged at the fixed liquid outlet part of the liquid outlet pipe.

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

through heater surface coating nanometer electric heat membrane, improve the heating efficiency of heater, reduce the power loss that heating power brought, keep warm to the heater through the heat preservation, improve thermal conductivity, simultaneously through temperature sensor and heater cooperation, reduce the heater and do not have the liquid phenomenon that dry combustion method leads to the heater to burn out to reduce the potential safety hazard that the burning out brought through fire-retardant shell.

Drawings

In order to more clearly illustrate the technical solution in the embodiments of the present invention, the drawings used in the description of the embodiments are briefly introduced below.

Fig. 1 is a schematic view of the overall structure of a nano film-coated quartz heater according to an embodiment of the present invention;

fig. 2 is a sectional view of the overall structure of the nano film-coated quartz heater in the embodiment of the present invention.

Description of the figures

1. The flame-retardant shell 2, the heater 3, the liquid outlet pipe 4, the liquid inlet pipe 5, the liquid leakage sensor 6 and the temperature sensor.

Detailed Description

The technical solution of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention.

As shown in fig. 1 and 2, a nano-coated quartz heater includes: fire-retardant shell 1 (fire-retardant shell 1 can comprise a fire-retardant portion and two supporting parts, and the both ends of fire-retardant portion are located to two supporting parts, wherein, fire-retardant portion can set the rectangle column into and also set cylindricly, wherein, two supporting parts can set the rectangle into and also set semicircular), be equipped with an inlet and a liquid outlet in fire-retardant shell 1, the both sides of fire-retardant shell 1 are located to inlet and liquid outlet branch, and the inlet is less than the liquid outlet setting (fire-retardant shell 1 bottom can be located to the inlet here, fire-retardant shell 1 top can be located to the liquid outlet). Be equipped with a heater 2 in fire-retardant shell 1, and heater 2 is equipped with a feed liquor pipe 4 and a drain pipe 3, and feed liquor pipe 4 passes the inlet and extends to the fire-retardant shell 1 outside, and drain pipe 3 passes the liquid outlet and extends to the fire-retardant shell 1 outside, and heater 2 wholly presents the column setting (the cross section of heater 2 is circular).

The phenomenon that the heater 2 is locally damaged due to the fact that the heater 2 is not full of liquid is prevented through the liquid inlet and outlet, the service life of the heater 2 is prolonged, and the flame-retardant shell 1 is made of V2-grade fireproof plastic.

The liquid outlet pipe 3 passes through the liquid outlet and extends to the outer side of the flame-retardant shell 1, a liquid sensor is additionally arranged at the liquid outlet of the liquid outlet pipe 3, and the liquid sensor prevents the phenomenon of no liquid dry burning.

The outer side wall covering film of the heater 2 is provided with a nano electrothermal film, the nano electrothermal film can adopt a nano tin oxide film or a nano graphene film, a heat preservation layer is arranged between the flame-retardant shell 1 and the heater 2, the heat preservation layer is specifically wrapped by asbestos, the heat preservation and the heat dissipation rate reduction are achieved, and the phenomenon that the flame-retardant shell 1 is damaged due to overhigh heat is reduced.

As shown in figures 1 and 2, during operation, liquid enters the heater 2 through the liquid inlet pipe 4, the nano electrothermal film of the heater 2 starts to drive the heater 2 to operate, the heater 2 heats the liquid inside, and the liquid flows out of the liquid outlet pipe 3 after the liquid inside the heater 2 is filled.

When the liquid sensor on the liquid outlet pipe 3 can not sense the liquid to flow out for a long time, the power supply of the heater 2 is cut off by the liquid sensor, and the heater 2 stops working.

The temperature sensor 6 is provided with a numerical value higher than the normal use temperature, and when no liquid dry combustion occurs in the heater 2 and the internal temperature of the heater 2 reaches a set numerical value, the temperature sensor 6 drives the heater 2 to be powered off.

When the heater 2 has a liquid leakage phenomenon, the liquid leakage sensor 5 is triggered to stop driving the liquid into the heater 2, and meanwhile, the heater 2 is powered off to reduce economic loss.

Various modifications to these embodiments will be readily apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the spirit or scope of the invention.

Claims (4)

1. A nano-coated quartz heater, comprising:

the flame-retardant shell is internally provided with a liquid inlet and a liquid outlet;

the heater is arranged in the flame-retardant shell and is provided with a liquid inlet pipe and a liquid outlet pipe, the liquid inlet pipe penetrates through the liquid inlet and extends to the outer side of the flame-retardant shell, and the liquid outlet pipe penetrates through the liquid outlet and extends to the outer side of the flame-retardant shell; the outer side wall of the heater is coated with a nano electrothermal film, and a heat insulation layer is arranged between the flame-retardant shell and the heater;

the leakage inductor is fixed in the flame-retardant shell and is arranged right below the heater;

the temperature sensor is fixedly connected with the heater, and the temperature sensor extends into the heater.

2. The nano-coated quartz heater according to claim 1, wherein the flame retardant shell is made of fire-retardant plastic of V2 grade.

3. The nano coated quartz heater according to claim 1, wherein the liquid inlet and the liquid outlet are disposed at two sides of the flame retardant shell, and the liquid inlet is disposed lower than the liquid outlet.

4. The nano-coated quartz heater according to claim 1, wherein a liquid sensor is installed at a fixed liquid outlet of the liquid outlet pipe.

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