CN218469529U - Green brick temperature measuring device - Google Patents

Abstract

The utility model discloses a green brick temperature measuring device, which belongs to the technical field of ceramic tile production equipment and comprises a conveying mechanism and a temperature measuring component; the temperature measuring component is used for measuring the temperature of the green brick; the heating mechanism and the cooling mechanism are respectively arranged above the conveying mechanism; the temperature measuring component comprises a first temperature measuring mechanism and a second temperature measuring mechanism; and the heating mechanism and the cooling mechanism are arranged between the first temperature measuring mechanism and the second temperature measuring mechanism. The utility model discloses a top at conveying mechanism sets up heating mechanism and cooling body, and set up the temperature of temperature measurement subassembly around heating or cooling to the adobe, when the temperature of the adobe that the drying kiln dried out is not in the required temperature range of glazing porcelain, accessible heating mechanism or cooling body make the adobe cooling or heat up once more, thereby before making the adobe carry the glaze line, the temperature of adobe can reach the required temperature of glazing porcelain, and then can reduce the condition that the adobe temperature can't reach the requirement of glazing porcelain after the adobe drying appears.

Description

Green brick temperature measuring device

Technical Field

The utility model relates to a ceramic tile production facility technical field, in particular to adobe temperature measuring device.

Background

The production process of the ceramic tile comprises a raw material preparation stage, a forming stage, a glazing stage, a glaze firing stage and the like, wherein in the forming stage, a green brick still has certain moisture, and the strength and the hardness of the green brick cannot be used for glazing, so the green brick needs to be dried before glazing. After the adobe is dried by the drying kiln, the temperature of the adobe can cause influence to the glazing quality, if the temperature of the adobe is too high or too low during the glazing of the adobe, the condition that the glazing is not uniform or the ground coat is easy to fall off can occur, therefore, the temperature of the dried adobe needs to be controlled within a certain range to better perform the glazing operation. However, after the green bricks are dried by the drying kiln, the temperature of the green bricks can not meet the glazing requirement, and the glaze surface defects are more after the green bricks are glazed, so that the yield of the ceramic tiles is reduced.

It is seen that improvements and enhancements in the prior art are needed.

SUMMERY OF THE UTILITY MODEL

In view of the foregoing prior art, an object of the utility model is to provide a adobe temperature measuring device aims at reducing the condition that the dry back adobe temperature of adobe can't reach the requirement of glazing porcelain of appearing.

In order to achieve the purpose, the utility model adopts the following technical proposal:

a green brick temperature measuring device comprises a conveying mechanism and a temperature measuring assembly; the temperature measuring component is used for measuring the temperature of the green brick; the device also comprises a controller, and a heating mechanism and a cooling mechanism which are respectively arranged above the conveying mechanism; the temperature measuring assembly comprises a first temperature measuring mechanism and a second temperature measuring mechanism; the heating mechanism and the cooling mechanism are respectively electrically connected with the controller, and are arranged between the first temperature measuring mechanism and the second temperature measuring mechanism; the cooling mechanism is used for cooling the green bricks, and the heating mechanism is used for heating the green bricks.

In the green brick temperature measuring device, the cooling mechanism comprises an air outlet pipe and an air blower connected with the air outlet pipe; the air outlet pipe is erected above the conveying mechanism along the width direction of the conveying mechanism, and an air blowing port arranged along the length direction of the air outlet pipe is formed in the air outlet pipe.

In the green brick temperature measuring device, the heating mechanism is an infrared heating tube arranged along the width direction of the conveying mechanism.

In the green brick temperature measuring device, a reflecting cover is erected above the conveying mechanism; the infrared heating tube is arranged in the reflecting cover, and the reflecting cover is used for reflecting heat generated by the infrared heating tube to the conveying mechanism.

Furthermore, the green brick temperature measuring device also comprises a second temperature measuring mechanism arranged above the conveying mechanism; the second temperature measuring mechanism is used for measuring the temperature of the green bricks on the conveying mechanism; and the heating mechanism and the cooling mechanism are arranged between the first temperature measuring mechanism and the second temperature measuring mechanism.

In the green brick temperature measuring device, the first temperature measuring mechanism and the second temperature measuring mechanism are both optical fiber infrared thermometers.

In the green brick temperature measuring device, the first temperature measuring mechanism is arranged at the upstream of the second temperature measuring mechanism; the green brick temperature measuring device also comprises a dust suction pipe arranged at the downstream of the second temperature measuring mechanism and a suction fan connected with the dust suction pipe; the dust absorption pipe is erected above the conveying mechanism along the width direction of the conveying mechanism, and a dust absorption opening arranged along the length direction of the dust absorption pipe is formed in the dust absorption pipe.

In the green brick temperature measuring device, the dust suction pipe is connected with a dust conveying pipe; the dust conveying pipe is connected with a cyclone separator, and the cyclone separator is connected with the suction fan.

Has the advantages that:

the utility model discloses a top at conveying mechanism sets up heating mechanism and cooling body, and set up temperature measurement subassembly and heat or measure the temperature around the cooling to the adobe, the temperature of the adobe that the drying kiln goes out is not when glazing required temperature range, accessible heating mechanism or cooling body make the adobe cooling or heat up once more, thereby ensure before the adobe carries the glaze line, the temperature of adobe can reach the required temperature of glazing porcelain, and then can reduce the condition that the adobe temperature can't reach the requirement of glazing porcelain after the adobe drying appears, the adobe drenches the glaze after, the glaze defect can reduce, the yields of ceramic tile product also can increase.

Drawings

Fig. 1 is a schematic structural diagram of a green brick temperature measuring device provided by the present invention.

Fig. 2 is a schematic structural diagram of the green brick temperature measuring device provided by the utility model II.

Reference numerals:

1-a conveying mechanism; 2-a second temperature measuring mechanism; 3-a first temperature measuring mechanism; 4-a heating mechanism;

5-a cooling mechanism; 501-air outlet pipe; 502-a blower; 503-an air blowing port;

6-a reflector;

7-a dust suction pipe; 701-a dust suction port;

8-a suction fan; 9-dust conveying pipe; 10-cyclone separator.

Detailed Description

The utility model provides a adobe temperature measuring device, for making the utility model discloses a purpose, technical scheme and effect are clearer, clear and definite, and it is right that the following refers to the attached drawing and the embodiment is lifted the utility model discloses do further detailed description. It should be understood that the specific embodiments described herein are for purposes of illustration only and are not intended to limit the invention.

In the present invention, the terms "upper", "lower", "left", "right", "front", "rear", "top", "bottom", "inner", "outer", "middle", "vertical", "horizontal", "lateral", "longitudinal", and the like indicate the orientation or positional relationship based on the orientation or positional relationship shown in the drawings. These terms are used primarily to better describe the invention and its embodiments, and are not intended to limit the indicated devices, elements or components to a particular orientation or to be constructed and operated in a particular orientation. Moreover, some of the above terms may be used to indicate other meanings besides the orientation or positional relationship, for example, the term "on" may also be used to indicate some kind of attachment or connection relationship in some cases. The specific meaning of these terms in the present invention can be understood by those of ordinary skill in the art as appropriate.

Furthermore, the terms "mounted," "disposed," "provided," "connected," and "connected" are to be construed broadly. For example, it may be a fixed connection, a removable connection, or a unitary construction; can be a mechanical connection, or an electrical connection; may be directly connected, or indirectly connected through intervening media, or may be in internal communication between two devices, elements or components. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

Furthermore, the terms "first," "second," and the like, are used primarily to distinguish one device, element, or component from another (the specific nature and configuration may be the same or different), and are not used to indicate or imply the relative importance or number of the indicated devices, elements, or components. "plurality" means two or more unless otherwise specified.

As shown in fig. 1 and 2, the utility model provides a green brick temperature measuring device, which comprises a conveying mechanism 1 and a temperature measuring component arranged above the conveying mechanism 1; the temperature measuring component is used for measuring the temperature of the green brick and comprises a first temperature measuring mechanism 3 and a second temperature measuring mechanism 2; furthermore, the green brick temperature measuring device also comprises a controller, and a heating mechanism 4 and a cooling mechanism 5 which are respectively arranged above the conveying mechanism 1; the heating mechanism 4 and the cooling mechanism 5 are respectively electrically connected with the controller, and the heating mechanism 4 and the cooling mechanism 5 are both arranged between the first temperature measuring mechanism 3 and the second temperature measuring mechanism 2; the cooling mechanism 5 is used for cooling the green bricks on the conveying mechanism 1, and the heating mechanism 4 is used for heating the green bricks on the conveying mechanism 1. It is understood that the conveying means 1 is prior art and is not within the scope of the present application; the length of the conveying mechanism 1 can be set according to actual production requirements, and the length of the conveying mechanism 1 shown in the attached drawings of fig. 1 and 2 in the specification of the application does not represent the actual length.

Conveying mechanism 1 can set up a plurality ofly to link up with the kiln tail of drying kiln, accessible conveying mechanism 1 will be carried the brick adobe through the drying to the glaze line after the brick adobe is seen off by the kiln tail of drying kiln. When the green bricks on the conveying mechanism 1 pass below the first temperature measuring mechanism 3, the first temperature measuring mechanism 3 can measure the temperature of the green bricks. When the temperature of the green brick measured by the first temperature measuring mechanism 3 is not within the range (usually 85 ℃ to 90 ℃) of the temperature required for glazing, for example, when the temperature of the green brick measured by the first temperature measuring mechanism 3 is lower than the minimum green brick temperature required for glazing, the heating mechanism 4 can be turned on by the controller, so that the temperature of the green brick is raised by the heating mechanism 4; and when the temperature of the green brick measured by the first temperature measuring mechanism 3 is higher than the maximum temperature required by glazing, the cooling mechanism 5 can be started through the controller, and the green brick is cooled through the cooling mechanism 5.

The second temperature measuring mechanism 2 can measure the temperature of the heated or cooled green bricks, so that the production personnel can know the temperature rise or temperature reduction degree of the green bricks, and the temperature of the green bricks can reach the temperature required for glazing.

The utility model discloses a top at conveying mechanism 1 sets up adobe heating mechanism 4 and adobe cooling body 5, and make heating mechanism 4 and cooling body 5 locate between first temperature measurement mechanism 3 and second temperature measurement mechanism 2, the temperature of the adobe that first temperature measurement mechanism 3 measured is not when glazing required temperature range, accessible heating mechanism 4 or cooling body 5 make the adobe cooling or heat up once more, thereby before making the adobe carry the glaze line, the temperature of adobe can reach the required temperature of glazing porcelain, and then can reduce the condition that the adobe temperature can't reach the requirement of glazing porcelain after the adobe drying appears, the adobe drenches the glaze back, the glaze defect can reduce, the yields of ceramic tile product also can increase.

In one embodiment, the cooling mechanism 5 includes an air outlet pipe 501 and a blower 502 connected to the air outlet pipe 501; the air outlet pipe 501 is erected above the conveying mechanism 1 along the width direction of the conveying mechanism 1, and an air blowing port 503 arranged along the length direction of the air outlet pipe 501 is arranged on the air outlet pipe 501. In the embodiment, air is blown into the air outlet pipe 501 through the air blower 502, and when green bricks pass through the lower part of the air outlet pipe 501, the air outlet pipe 501 blows air to the green bricks, so that the green bricks are cooled.

In one embodiment, the number of the cooling mechanisms 5 is not less than one. When the temperature of the green bricks cannot be quickly reduced to the required glazing temperature through the single cooling mechanism 5, the cooling mechanisms 5 can be opened to blow air to the green bricks so that the temperature of the green bricks is quickly reduced to the required glazing temperature, and therefore the number of the green bricks of which the temperature cannot meet the glazing requirement can be further reduced.

In one embodiment, the heating mechanism 4 is an infrared heating tube disposed along the width direction of the conveying mechanism 1. The working power of the infrared heating tube can be adjusted through the controller, so that the phenomenon that the conveying belt is damaged due to overhigh heating temperature of the infrared heating tube can be avoided, and meanwhile, the green bricks can be heated.

In one embodiment, the number of the heating mechanisms 4 is not less than one. When the temperature of the green bricks cannot be quickly raised to the required glazing temperature through the single heating mechanism 4, the plurality of heating mechanisms 4 can be started to quickly raise the temperature of the green bricks to the required glazing temperature, so that the number of the green bricks of which the temperature cannot meet the glazing requirement can be further reduced.

When the temperature of the green brick measured by the second temperature measuring mechanism 2 reaches the temperature required by glazing, the using number of the cooling mechanism 5 and the heating mechanism 4 and the working power of the heating mechanism 4 do not need to be adjusted, so that the temperature of the green brick subsequently sent out by the drying kiln can be kept in the temperature range required by glazing. However, when the first temperature measuring means 3 detects a change in the temperature of the dried green bricks again, it is necessary to adjust the number of the cooling means 5 and the heating means 4 and the operating power of the heating means 4 again.

In one embodiment, a reflective cover 6 is arranged above the conveying mechanism 1; the infrared heating tube is arranged in the reflecting cover 6, and the reflecting cover 6 is used for reflecting heat generated by the infrared heating tube to the conveying mechanism 1. Through setting up bowl 6, can reflect the heating effect of adobe to the adobe with most heat that infrared heating tube produced.

In one embodiment, the first temperature measuring mechanism 3 and the second temperature measuring mechanism 2 are both optical fiber infrared thermometers. The optical fiber infrared thermometer comprises a temperature measuring probe and a detecting instrument, wherein the detecting instrument has a temperature display function, and is convenient for production personnel to know the temperature of the green bricks below the temperature measuring mechanism.

In one embodiment, the green brick temperature measuring device further comprises a dust suction pipe 7 arranged at the downstream of the second temperature measuring mechanism 2 and a suction fan 8 connected with the dust suction pipe 7; the dust suction pipe 7 is erected above the conveying mechanism 1 along the width direction of the conveying mechanism 1, and a dust suction port 701 arranged along the length direction of the dust suction pipe 7 is arranged on the dust suction pipe 7. This embodiment absorbs the adobe bits on the brick face through setting up dust absorption pipe 7, and when the frit was applyed on the brick face, the glaze defect can further reduce, and the yields of ceramic tile also can increase.

In one embodiment, the dust suction pipe 7 is connected with a dust conveying pipe 9; the dust conveying pipe 9 is connected with a cyclone separator 10, and the cyclone separator 10 is connected with the suction fan 8. After the green scraps on the brick surface are sucked into the dust suction pipe 7, the green scraps are conveyed into the cyclone separator 10 through the dust conveying pipe 9 under the action of the suction fan 8, and the green scraps are collected by the bottom of the cyclone separator 10 through the treatment of the cyclone separator 10, so that the green scraps are not discharged into the atmosphere, and the collected green scraps can be recycled as blanks.

To sum up, the utility model discloses a top at conveying mechanism sets up heating mechanism and cooling body to set up temperature measurement subassembly and heat or measure the temperature around the cooling to the adobe, when the temperature of the adobe that the drying kiln dried out is not when glazing required temperature range, accessible heating mechanism or cooling body make the adobe cooling or heat up once more, thereby before guaranteeing that the adobe carries the glaze line, the temperature of adobe can reach the required temperature of glazing porcelain, and then can reduce the condition that the adobe temperature can't reach the requirement of glazing porcelain after the adobe drying appears, the adobe drenches the glaze back, the glaze defect can reduce, the yields of ceramic tile product also can increase.

It should be understood that equivalent alterations and modifications can be made by those skilled in the art according to the technical solution of the present invention and the inventive concept thereof, and all such alterations and modifications should fall within the scope of the appended claims.

Claims (7)

1. A green brick temperature measuring device comprises a conveying mechanism and a temperature measuring assembly; the temperature measuring component is used for measuring the temperature of the green brick; the device is characterized by also comprising a controller, a heating mechanism and a cooling mechanism which are respectively arranged above the conveying mechanism; the temperature measuring assembly comprises a first temperature measuring mechanism and a second temperature measuring mechanism; the heating mechanism and the cooling mechanism are respectively electrically connected with the controller, and are arranged between the first temperature measuring mechanism and the second temperature measuring mechanism; the cooling mechanism is used for cooling the green bricks, and the heating mechanism is used for heating the green bricks.

2. The apparatus according to claim 1, wherein the cooling mechanism comprises an air outlet pipe and a blower connected to the air outlet pipe; the air outlet pipe is erected above the conveying mechanism along the width direction of the conveying mechanism, and an air blowing port arranged along the length direction of the air outlet pipe is formed in the air outlet pipe.

3. The apparatus according to claim 1, wherein the heating means is an infrared heating tube disposed along the width of the conveying means.

4. The apparatus according to claim 3, wherein a reflector is installed above the conveying mechanism; the infrared heating tube is arranged in the reflecting cover, and the reflecting cover is used for reflecting heat generated by the infrared heating tube to the conveying mechanism.

5. The apparatus according to claim 1, wherein the first and second thermometry mechanisms are fiber infrared thermometers.

6. The apparatus according to claim 1, wherein the first temperature measuring mechanism is disposed upstream of the second temperature measuring mechanism; the green brick temperature measuring device also comprises a dust suction pipe arranged at the downstream of the second temperature measuring mechanism and a suction fan connected with the dust suction pipe; the dust absorption pipe is erected above the conveying mechanism along the width direction of the conveying mechanism, and a dust absorption opening arranged along the length direction of the dust absorption pipe is formed in the dust absorption pipe.

7. The apparatus according to claim 6, wherein the dust suction pipe is connected to a dust duct; the dust conveying pipe is connected with a cyclone separator, and the cyclone separator is connected with the suction fan.

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