CN220455201U - Quartz sand refractoriness detection device - Google Patents

Abstract

The utility model relates to the technical field of refractoriness detection, in particular to a quartz sand refractoriness detection device; including furnace body, electric heating pipe and cooling module, electric heating pipe sets up in the inside of furnace body, cooling module includes the heat dissipation stove, a support, the actuating cylinder, place board and radiator module, the heat dissipation stove is linked together with the furnace body, and be located the below of furnace body, support and heat dissipation stove fixed connection, and be located the lateral wall of heat dissipation stove, actuating cylinder and support fixed connection, place the output of board and actuating cylinder and be connected, and slide and set up in the heat dissipation stove, radiator module is connected with the heat dissipation stove, through above-mentioned structure, push the quartz sand that last batch detected into the heat dissipation stove in waiting to cool down, put into the fire-resistant degree detection in the furnace body with the latter batch of quartz sand again, take out the quartz sand that the former batch detected from the heat dissipation stove in the fire-resistant degree detection, obtain the effect that improves quartz sand fire-resistant degree detection efficiency.

Description

Quartz sand refractoriness detection device

Technical Field

The utility model relates to the technical field of refractoriness detection, in particular to a quartz sand refractoriness detection device.

Background

Currently, in quartz sand production, the refractoriness of the quartz sand is required to be detected so as to detect the service performance of the quartz sand; the utility model discloses a refractoriness detection device for quartz sand processing in the prior art in the patent application of application number 202122194183.3, including furnace body, electric heating pipe, adopts electric heating pipe heating, carries out the refractoriness to the quartz sand in the furnace body and detects.

However, in the above structure, after the last batch of quartz sand is detected, the operator is required to take out the detected quartz sand from the furnace body after waiting for cooling, and when a plurality of batches of quartz sand are required to be detected, a great deal of time is required to wait for taking out the detected quartz sand, so that the detection efficiency is affected.

Disclosure of Invention

The utility model aims to provide a quartz sand refractoriness detection device, which solves the problem that when a plurality of batches of quartz sand are detected, a great deal of time is required to wait for taking out the detected quartz sand, and the detection efficiency is affected.

In order to achieve the above purpose, the quartz sand refractoriness detection device comprises a furnace body, an electric heating pipe and a cooling module, wherein the electric heating pipe is arranged in the furnace body, the cooling module comprises a heat dissipation furnace, a support, a driving air cylinder, a placement plate and a heat dissipation assembly, the heat dissipation furnace is communicated with the furnace body and is positioned below the furnace body, the support is fixedly connected with the heat dissipation furnace and is positioned on the outer side wall of the heat dissipation furnace, the driving air cylinder is fixedly connected with the support, the placement plate is connected with the output end of the driving air cylinder and is arranged in the heat dissipation furnace in a sliding manner, and the heat dissipation assembly is connected with the heat dissipation furnace.

The cooling module further comprises a pushing inclined plate which is fixedly connected with the heat dissipation furnace and is located above the placing plate.

The cooling module further comprises a protection frame, the protection frame is communicated with the heat dissipation furnace, and the placing plate is matched with the protection frame.

The heat dissipation assembly comprises a blower and an air pipe, wherein the air pipe penetrates through the heat dissipation furnace, and the blower is communicated with the air pipe.

The cooling module further comprises a stirring assembly, and the stirring assembly is arranged in the heat dissipation furnace.

The stirring assembly comprises a driving motor, a speed reducer, a shaft rod and a stirring block, wherein the driving motor is fixedly connected with the heat dissipation furnace and is positioned on the inner side wall of the heat dissipation furnace, the speed reducer is connected with the output end of the driving motor, the shaft rod is connected with the output end of the speed reducer, and the stirring block is fixedly connected with the outer side wall of the shaft rod.

According to the quartz sand refractoriness detection device, the quartz sand which is detected in the previous batch is pushed into the heat dissipation furnace to wait for cooling, then the quartz sand in the next batch is put into the furnace body to detect the refractoriness, and the quartz sand which is detected in the previous batch is taken out of the heat dissipation furnace while the refractoriness of the quartz sand in the next batch is detected, so that the effect of improving the refractoriness detection efficiency of the quartz sand is achieved.

Drawings

In order to more clearly illustrate the embodiments of the utility model or the technical solutions in the prior art, the drawings that are required in the embodiments or the description of the prior art will be briefly described, it being obvious that the drawings in the following description are only some embodiments of the utility model, and that other drawings may be obtained according to these drawings without inventive effort for a person skilled in the art.

Fig. 1 is a schematic overall structure of a first embodiment of the present utility model.

Fig. 2 is an overall structural elevation view of the first embodiment of the present utility model.

Fig. 3 is a cross-sectional view of the entire structure of the first embodiment of the present utility model.

Fig. 4 is a schematic overall structure of a second embodiment of the present utility model.

Fig. 5 is an overall structural elevation view of a second embodiment of the present utility model.

Fig. 6 is a cross-sectional view of the entire structure of a second embodiment of the present utility model.

101-furnace body, 102-electric heating pipe, 103-heat dissipation furnace, 104-bracket, 105-driving cylinder, 106-protection frame, 107-placing plate, 108-blower, 109-air pipe, 110-pushing sloping plate, 201-driving motor, 202-speed reducer, 203-shaft lever and 204-stirring block.

Detailed Description

Embodiments of the present utility model are described in detail below, examples of which are illustrated in the accompanying drawings, wherein like or similar reference numerals refer to like or similar elements or elements having like or similar functions throughout. The embodiments described below by referring to the drawings are illustrative and intended to explain the present utility model and should not be construed as limiting the utility model.

First embodiment

Referring to fig. 1 to 3, fig. 1 is a schematic overall structure of the first embodiment, fig. 2 is a front overall structure view of the first embodiment, and fig. 3 is a sectional overall structure view of the first embodiment.

The utility model provides a quartz sand refractoriness detection device which comprises: the electric heating furnace comprises a furnace body 101, an electric heating pipe 102 and a cooling module, wherein the cooling module comprises a heat radiation furnace 103, a bracket 104, a driving cylinder 105, a placing plate 107, a heat radiation assembly, a pushing inclined plate 110 and a protection frame 106, and the heat radiation assembly comprises a blower 108 and an air pipe 109.

For the present embodiment, the electric heating pipe 102 is disposed inside the furnace body 101, quartz sand is placed into the furnace body 101, and the electric heating pipe 102 is used for heating, so as to detect the refractoriness of the quartz sand in the furnace body 101.

The heat dissipation furnace 103 is communicated with the furnace body 101 and is located below the furnace body 101, the support 104 is fixedly connected with the heat dissipation furnace 103 and is located on the outer side wall of the heat dissipation furnace 103, the driving cylinder 105 is fixedly connected with the support 104, the placing plate 107 is connected with the output end of the driving cylinder 105 and is slidably arranged in the heat dissipation furnace 103, the heat dissipation assembly is connected with the heat dissipation furnace 103, an electric heating pipe 102 is used for heating to detect the refractoriness of quartz sand in the furnace body 101, after detection is completed, the driving cylinder 105 is driven to operate, the placing plate 107 is pulled away from the heat dissipation furnace 103, the detected quartz sand falls into the heat dissipation furnace 103, the detected quartz sand is cooled by the heat dissipation assembly, and then the next batch of quartz sand is placed into the furnace body 101 for refractoriness detection; pushing the quartz sand which is detected in the previous batch into the heat dissipation furnace 103 for cooling, putting the quartz sand in the next batch into the furnace body 101 for refractoriness detection, and taking the quartz sand which is detected in the previous batch out of the heat dissipation furnace 103 while detecting the refractoriness of the quartz sand in the next batch, thereby obtaining the effect of improving the refractoriness detection efficiency of the quartz sand.

Secondly, the pushing inclined plate 110 is fixedly connected with the heat dissipation furnace 103 and is located above the placing plate 107, so as to drive the driving cylinder 105 to operate, the driving cylinder 105 withdraws the placing plate 107 from the heat dissipation furnace 103, and the pushing inclined plate 110 scrapes the quartz sand after detection.

Meanwhile, the protection frame 106 is connected with the heat dissipation furnace 103, and the placement plate 107 is matched with the protection frame 106, the protection frame 106 protects the placement plate 107, and personnel are prevented from being injured due to the fact that the personnel contact with the placement plate 107 at high temperature.

In addition, the air duct 109 penetrates the heat dissipation furnace 103, the blower 108 is communicated with the air duct 109, and the blower 108 blows air to the air duct 109, so that the inside of the heat dissipation furnace 103 is cooled rapidly.

When the utility model is used for detecting the refractoriness of a plurality of batches of quartz sand, the quartz sand is placed into the furnace body 101, the electric heating pipe 102 is adopted for heating, the refractoriness of the quartz sand in the furnace body 101 is detected, after the detection is finished, the driving cylinder 105 is driven to operate, the placing plate 107 is pulled out from the heat dissipation furnace 103 by the driving cylinder 105, the detected quartz sand is scraped by the pushing inclined plate 110, the detected quartz sand falls into the heat dissipation furnace 103, the detected quartz sand is cooled by the heat dissipation assembly, and then the next batch of quartz sand is placed into the furnace body 101 for refractoriness detection; pushing the quartz sand which is detected in the previous batch into the heat dissipation furnace 103 for cooling, putting the quartz sand in the next batch into the furnace body 101 for refractoriness detection, and taking the quartz sand which is detected in the previous batch out of the heat dissipation furnace 103 while detecting the refractoriness of the quartz sand in the next batch, thereby obtaining the effect of improving the refractoriness detection efficiency of the quartz sand.

Second embodiment

Referring to fig. 4 to 6, fig. 4 is a schematic overall structure of the second embodiment, fig. 5 is a front overall structure view of the second embodiment, and fig. 6 is a sectional overall structure view of the second embodiment.

On the basis of the first embodiment, the quartz sand refractoriness detection device comprises a cooling module, and the stirring assembly comprises a driving motor 201, a speed reducer 202, a shaft lever 203 and a stirring block 204.

The stirring component is arranged in the heat dissipation furnace 103, and is used for stirring quartz sand detected in the heat dissipation furnace 103, so that cooling efficiency is improved.

The driving motor 201 is fixedly connected with the heat dissipation furnace 103 and is located on the inner side wall of the heat dissipation furnace 103, the speed reducer 202 is connected with the output end of the driving motor 201, the shaft rod 203 is connected with the output end of the speed reducer 202, the stirring block 204 is fixedly connected with the outer side wall of the shaft rod 203, the driving motor 201 is driven to operate, the speed reducer 202 is driven to operate with the driving motor 201, the shaft rod 203 is driven to rotate, the stirring block 204 is driven to rotate, and quartz sand detected in the heat dissipation furnace 103 is stirred.

The driving motor 201 is driven to operate, the speed reducer 202 and the driving motor 201 operate, the shaft lever 203 is driven to rotate, the stirring block 204 is driven to rotate, stirring treatment is carried out on quartz sand detected in the heat dissipation furnace 103, and cooling efficiency is improved.

The above disclosure is only illustrative of two preferred embodiments of the present utility model, and it is not intended to limit the scope of the claims, and those skilled in the art will understand that all or part of the procedures described above may be performed, and that equivalent changes may be made, which are encompassed by the present utility model.

Claims (6)

1. The quartz sand refractoriness detection device comprises a furnace body and an electric heating pipe, wherein the electric heating pipe is arranged in the furnace body,

the cooling module comprises a heat radiation furnace, a support, a driving air cylinder, a placing plate and a heat radiation component, wherein the heat radiation furnace is communicated with the furnace body and is positioned below the furnace body, the support is fixedly connected with the heat radiation furnace and is positioned on the outer side wall of the heat radiation furnace, the driving air cylinder is fixedly connected with the support, the placing plate is connected with the output end of the driving air cylinder and is arranged in the heat radiation furnace in a sliding manner, and the heat radiation component is connected with the heat radiation furnace.

2. The quartz sand refractoriness testing apparatus according to claim 1, wherein,

the cooling module further comprises a pushing inclined plate which is fixedly connected with the heat dissipation furnace and is positioned above the placing plate.

3. The quartz sand refractoriness testing apparatus according to claim 1, wherein,

the cooling module further comprises a protection frame, the protection frame is communicated with the heat dissipation furnace, and the placing plate is matched with the protection frame.

4. The quartz sand refractoriness testing apparatus according to claim 1, wherein,

the heat dissipation assembly comprises a blower and an air pipe, wherein the air pipe penetrates through the heat dissipation furnace, and the blower is communicated with the air pipe.

5. The quartz sand refractoriness testing apparatus according to claim 1, wherein,

the cooling module further comprises a stirring assembly, and the stirring assembly is arranged in the heat dissipation furnace.

6. The quartz sand refractoriness testing apparatus according to claim 5, wherein,

the stirring assembly comprises a driving motor, a speed reducer, a shaft rod and a stirring block, wherein the driving motor is fixedly connected with the heat dissipation furnace and is positioned on the inner side wall of the heat dissipation furnace, the speed reducer is connected with the output end of the driving motor, the shaft rod is connected with the output end of the speed reducer, and the stirring block is fixedly connected with the outer side wall of the shaft rod.