CN218067969U

CN218067969U - Glass heat insulation energy-saving coating detection device

Info

Publication number: CN218067969U
Application number: CN202222212925.5U
Authority: CN
Inventors: 邢小健; 邢伟
Original assignee: Nantong Lejia Paint Co ltd
Current assignee: Nantong Lejia Paint Co ltd
Priority date: 2022-08-22
Filing date: 2022-08-22
Publication date: 2022-12-16
Anticipated expiration: 2032-08-22

Abstract

A glass heat insulation energy-saving coating detection device comprises a detection shell arranged in a detection box and a light source for providing illumination; the middle of the detection shell is connected with a partition board which divides the interior of the detection shell into two to three detection cavities, and a temperature sensor and a light sensor are respectively arranged at the same position in the detection cavities; an opening is formed in the upper end of the detection cavity and used for transmitting light; a supporting seat is arranged on the side wall of the detection shell and the upper end of the partition plate in an extending manner, a sealing gasket is adhered to the surface of the supporting seat, and a pressing strip is arranged above the sealing gasket; the support seat is connected with a plurality of studs, the upper ends of the studs penetrate through the pressing strips to be connected with butterfly nuts, and the pressing strips are locked by the butterfly nuts. Compared with the prior art, the utility model discloses a glass energy-conserving coating detection device that insulates against heat shines the glass that detects on the shell through the light source, utilizes temperature-sensing ware and light sensor feedback glass's thermal-insulated and printing opacity effect on display panel, and the coating thickness of glass is selected in the debugging of being convenient for, helps improving production technology.

Description

Glass heat insulation energy-saving coating detection device

Technical Field

The utility model relates to a coating detects technical field, specifically indicates a glass thermal-insulated energy-saving coating detection device.

Background

The heat-insulating energy-saving coating can effectively block partial sunlight irradiation, has a certain heat-insulating effect, reduces energy consumption in a building, and when glass is coated, the optimal coating thickness cannot be determined due to the fact that a detection device is lacked for detecting the coating effect, so that the production process is frequently changed.

SUMMERY OF THE UTILITY MODEL

The to-be-solved technical problem of the utility model is to above-mentioned prior art not enough, and provide a glass thermal-insulated energy-saving coating detection device.

In order to solve the technical problem, the utility model discloses a technical scheme is:

a glass heat insulation energy-saving paint detection device comprises a detection shell arranged in a detection box and a light source for providing illumination; the middle of the detection shell is connected with a partition board which divides the interior of the detection shell into two to three detection cavities, and a temperature sensor and a light sensor are respectively arranged at the same position in the detection cavities; an opening is formed in the upper end of the detection cavity and used for transmitting light; a supporting seat is arranged on the side wall of the detection shell and the upper end of the partition plate in an extending manner to the side surface, a sealing gasket is adhered to the surface of the supporting seat, and a pressing strip is arranged above the sealing gasket; the supporting seat is connected with a plurality of studs, the upper ends of the studs penetrate through the pressing strips to be connected with butterfly nuts, and the pressing strips are locked by the butterfly nuts.

Furthermore, the bottom of the detection shell is provided with an outward extending edge, and the extending edge is installed at the bottom of the detection box through a screw; the light source is installed above the detection box through the suspension rod and is located in the middle of the detection shell.

Furthermore, a heat insulation layer is arranged inside the box body of the detection box, a display panel is arranged above the detection box, a light source adjusting knob is arranged on the display panel, and the light source is adjustable within the range of 10 w-1000 w.

Furthermore, one side of the detection box is rotatably connected with a door plate, a circle of sealing ring is embedded and connected on a door frame of the detection box, and the door plate is closed and sealed with the detection box through the sealing ring.

Furthermore, a cushion block is arranged between the supporting seat and the pressing strip above the side wall of the detection shell.

Further, the light source adopts a white light lamp or an infrared lamp.

Furthermore, the temperature sensor thermosensitive probe and the light sensor adopt photosensitive diodes.

Compared with the prior art, the utility model discloses a glass energy-saving coating detection device that insulates against heat shines the glass on the detection shell through the light source, utilizes temperature-sensing ware and light sensor feedback glass's thermal-insulated and printing opacity effect on display panel, and the coating thickness of glass is selected in the debugging of being convenient for, helps improving production technology.

Drawings

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

FIG. 2 is an enlarged view at A in FIG. 1;

the device comprises a detection shell 1, a detection shell 2, a light source 3, a partition plate 4, a temperature sensor 5, a light sensor 6, glass 7, a support seat 8, a sealing gasket 9, a pressing strip 10, a stud 11, a butterfly nut 12, a cushion block 13, a detection box 14, an extending edge 15, a hanging rod 16, a display panel 17, a light source adjusting knob 18, a door plate 19 and a sealing ring.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below.

As shown in fig. 1 and 2, a glass heat-insulating energy-saving coating detection device comprises a detection shell 1 and a light source 2 for providing illumination, wherein a partition plate 3 is connected in the middle of the detection shell 1, the partition plate 3 divides the interior of the detection shell 1 into two detection cavities, a temperature sensor 4 and a light sensor 5 are respectively arranged at the same position in the two detection cavities, and the temperature sensor 4 and the light sensor 5 respectively adopt a thermosensitive probe and a photosensitive diode; detect the chamber upper end and be provided with the opening, glass 6 is installed in detecting chamber open-ended top, and the light source sees through glass and provides illumination to detecting intracavity portion, detects through thermosensitive probe and the photodiode that detect the intracavity.

Wherein, a supporting seat 7 is arranged on the side wall of the detection shell 1 and the upper end of the clapboard 3 in an extending way towards the side surface, a sealing gasket 8 is stuck on the surface of the supporting seat 7, a pressing strip 9 is arranged above the sealing gasket 8, the glass 6 is placed on the sealing gasket 8 of the supporting seat 7, and the pressing strip 9 is placed at the periphery of the glass 6; the support seat 7 is connected with a plurality of studs 10, the upper ends of the studs 10 penetrate through the pressing strips 9 to be connected with butterfly nuts 11, and the glass 6 is pressed by screwing the butterfly nuts 11.

As only one side of the pressing strip above the side wall of the detection shell 1 compresses the glass, the glass is prevented from being crushed, a cushion block 12 is arranged between the support seat 7 and the pressing strip 9 above the side wall of the detection shell 1, the pressing strip 9 above the partition plate 3 compresses the glass 6 on two sides simultaneously, and the pressing strip 9 above the partition plate 3 does not need to be supported by the cushion block.

In order to avoid the influence of the external environment on the detection result, the detection shell 1 and the light source 2 are arranged in the detection box 13, the bottom of the detection shell 1 is provided with an outward extending edge 14, the extending edge 14 is installed at the bottom of the detection box 13 through a screw, the light source 2 adopts a white light lamp or an infrared lamp, the light source 2 is installed above the detection box 13 through a hanging rod 15, and the light source 2 is located in the middle of the detection shell 1.

A heat insulation layer is arranged in the box body of the detection box 13 to avoid the influence of external temperature, a display panel 16 is arranged above the detection box 13, a light source adjusting knob 17 is arranged on the display panel 16, a light source is adjustable within the range of 10 w-1000 w, and the display panel 16 simultaneously displays the internal temperature of the detection cavity and whether the light sensor is switched on or not; one side of the detection box 13 is rotatably connected with a door plate 18, a circle of sealing ring 19 is embedded and connected on a door frame of the detection box 13, and the door plate 18 is closed and sealed with the detection box 13 through the sealing ring 19.

When the detection device is used, the common glass and the glass coated with the coating are arranged on the opening of the detection cavity for detection, and detection finds that the thicker the heat-insulating and energy-saving coating layer is, the better the heat-insulating effect is, but the thicker the heat-insulating and energy-saving coating is, the poorer the light transmittance of the glass is, namely, the heat-insulating property and the light transmittance are in inverse proportion, and when the thickness of the coating layer is 280-350 um, the heat-insulating effect is met, and the light transmittance of the glass under a darker light source is also met.

The present invention is not limited to the above-described embodiments, and those skilled in the art can make modifications or changes without departing from the spirit of the present invention.

Claims

1. The utility model provides a glass energy-conserving coating detection device that insulates against heat which characterized in that: comprises a detection shell arranged in a detection box and a light source for providing illumination; the middle of the detection shell is connected with a partition board which divides the interior of the detection shell into two to three detection cavities, and a temperature sensor and a light sensor are respectively arranged at the same position in the detection cavities; an opening is formed in the upper end of the detection cavity and used for transmitting light; a supporting seat is arranged on the side wall of the detection shell and the upper end of the partition plate in an extending manner to the side surface, a sealing gasket is adhered to the surface of the supporting seat, and a pressing strip is arranged above the sealing gasket; the support seat is connected with a plurality of studs, the upper ends of the studs penetrate through the pressing strips to be connected with butterfly nuts, and the pressing strips are locked by the butterfly nuts.

2. The glass heat-insulating energy-saving coating detection device according to claim 1, characterized in that: the bottom of the detection shell is provided with an outward extending edge, and the extending edge is installed at the bottom of the detection box through a screw; the light source is installed above the detection box through the suspension rod and is located in the middle of the detection shell.

3. The glass heat-insulating energy-saving coating detection device according to claim 1, characterized in that: the detection box is characterized in that a heat insulation layer is arranged inside the box body of the detection box, a display panel is arranged above the detection box, a light source adjusting knob is arranged on the display panel, and the light source is adjustable within the range of 10 w-1000 w.

4. The glass heat-insulating energy-saving coating detection device of claim 1, characterized in that: one side of the detection box is rotatably connected with a door plate, a circle of sealing ring is embedded and connected on a door frame of the detection box, and the door plate is closed and sealed with the detection box through the sealing ring.

5. The glass heat-insulating energy-saving coating detection device of claim 1, characterized in that: and a cushion block is arranged between the supporting seat and the pressing strip above the side wall of the detection shell.

6. The glass heat insulation energy-saving coating detection device according to any one of claims 1 to 5, characterized in that: the light source adopts a white light lamp or an infrared lamp.

7. The glass heat insulation energy-saving coating detection device according to any one of claims 1 to 5, characterized in that: the temperature sensor adopts a thermosensitive probe, and the light sensor adopts a photosensitive diode.