KR102106953B1 - A device for crushing the waste perlite - Google Patents

Abstract

A waste perlite pulverizing device according to one embodiment comprises: a supply part for supplying waste perlite; a pulverizing part for pulverizing the waste perlite provided from the supply part; a dust collection part for collecting dust from the pulverized waste perlite powder; and an exhaust part for discharging air, from which dust is removed, to the atmosphere. The dust collection part comprises a filtering member arranged at an upper side of the dust collection part and filtering dust from the pulverized waste perlite, and a discharging member arranged at a lower side of the dust collection part and discharging the waste perlite powder from which dust is removed. According to the present invention, perlite can be effectively pulverized.

Description

Waste Ferrite Grinding Device {A DEVICE FOR CRUSHING THE WASTE PERLITE}

The following examples relate to a waste ferrite grinding device.

Perlite, also known as pearl stone, is a natural glass with 2 to 5% crystal water. Volcanic lava or magma flows into the surface lake and is produced by rapid cooling. It has a light luster. Minerals called perlite include obsidian, perlite, and pine, and the chemical composition is similar to that of granite, except for loss of heat, but when baked at high temperatures, it expands into a hollow sphere. In this high-temperature heating process, 4-5% of the ferrite powder, which has no value as a finished product, is obtained.

The present invention relates to a device for pulverizing waste ferrite used as a heat insulating material or heat insulating material into a powder-like raw material from which foreign matter has been removed by a continuous process, and more specifically, perlite has a very stable chemical structure, heat retention and water repellency. As it has (發 水性), it is used for various purposes such as construction materials, agricultural gardening, etc. For the utilization of waste resources, it is possible to collect and pulverize waste ferrites that have already been used as insulation materials or heat insulating materials or sound absorbing materials for construction materials.

Subsequently, this is made into a powder and the reinforcing fibers and other foreign substances are removed from the filter to classify only fine powders of a certain size with a cyclone classifier, and fine particles with a large specific gravity in a foreign substance separation tank using the water repellency of the ferrite. It relates to a device for producing recycled ferrite raw materials by removing stone powder or metal powder.

In the conventional case, insulators in which perlite is used have been reclaimed or incinerated without recycling, but when reclaimed, it takes a long time to disassemble the insulator or insulator in which perrite is used, and generates various toxic gases during incineration. There were problems that caused environmental pollution problems.

Accordingly, there was a problem that not only wastes recyclable resources but also causes various environmental pollutions, but due to the nature of the waste perlite, separation of reinforcing fibers contained therein and separation of foreign substances such as fine stone powder or metal powder mixed during use. There is a problem that the efficiency of recycling and utilizing the waste ferrite is not high.

Republic of Korea Utility Model No. 20-0260601 proposed a waste ferrite raw material recycling device.

An object according to an embodiment is to provide a waste ferrite grinding device for effectively pulverizing the waste ferrite.

An object according to an embodiment is to provide a waste ferrite crushing apparatus capable of preventing pollution from being generated by dust that may be generated in the process of pulverizing the waste ferrite.

An object according to an embodiment is to provide a waste ferrite grinding apparatus to form a pulverized product having a certain level of uniformity.

The waste ferrite crushing apparatus according to an embodiment includes a supply unit for supplying waste ferrite, a pulverization unit for pulverizing the waste parrite provided from the supply unit, a dust collecting unit for collecting dust from the pulverized waste ferrite powder, and air from which the dust is removed An exhaust portion for discharging to the middle, the dust collecting portion is disposed on the upper side of the dust collecting filter element for filtering dust from the pulverized waste ferrite and disposed on the lower side of the dust collecting portion to discharge the dust-free waste ferrite powder It may contain elements.

In addition, the waste ferrite pulverizing apparatus is disposed between the pulverizing part and the dust collecting part, the first transfer part transferring the pulverized waste ferrite powder to the dust collecting part and the waste ferrite powder pulverized by extending to one side from the discharge element of the dust collecting part It may include a second transfer unit for transferring the sieve to the outside of the waste ferrite grinding device.

At this time, between the filter element and the discharge element of the dust collecting portion is disposed a guide that decreases in width as it progresses from the upper side to the lower side, one end of the first transfer portion is disposed on the upper surface of the crushing portion, and the first transfer portion The other end of may be disposed on one side of the guide.

The exhaust portion, a bypass path extending from one side of the exhaust portion and connected to the filter element, a first sensor element and a first sensor element disposed inside the exhaust portion to measure the degree of contamination of air flowing through the exhaust portion When the degree of contamination of the air measured by exceeds a predetermined numerical value, a first control element for flowing the entire amount of air flowing through the exhaust portion to the dust collecting portion may be included.

In addition, the exhaust unit may further include a first blocking element disposed on one end of the bypass path connected to one side of the exhaust unit and hinged, and the first control element is hinged to the first blocking element. Optionally, the main path of the exhaust unit may be blocked or the bypass path may be blocked.

In addition, the crushing unit, a second sensor element disposed inside the crushing unit to measure the size of the pulverized waste ferrite powder, a second blocking capable of selectively opening and closing the path between the crushing unit and the first transfer unit It may include a second control element for controlling the operation of the second blocking element based on the value measured by the element and the second sensor element.

Accordingly, when the size of the pulverized waste ferrite powder measured by the second sensor element is smaller than a preset value, the second control element opens a path between the crushing unit and the first transfer unit, and the When the size of the pulverized waste ferrite powder measured by the second sensor element is greater than or equal to a preset value, a path between the crushing unit and the first transfer unit may be blocked by the second blocking element.

The waste ferrite grinding apparatus according to an embodiment may effectively pulverize the waste ferrite.

The waste ferrite grinding apparatus according to an embodiment may prevent pollution from being generated by dust that may be generated in the grinding process.

The waste ferrite grinding apparatus according to an embodiment may form a grinding material having a certain level of uniformity.

1 and 2 show a waste ferrite crushing apparatus of a waste ferrite regeneration system according to an embodiment.
3 shows a waste ferrite regeneration system according to an embodiment.
4 and 5 show a waste ferrite sorting apparatus of a waste ferrite regeneration system according to an embodiment.

Hereinafter, embodiments will be described in detail with reference to the accompanying drawings. The following description is one of several aspects of the embodiments, and the following description forms part of a detailed description of the embodiment.

However, in describing one embodiment, a detailed description of known functions or configurations will be omitted to clarify the gist of the present invention.

In addition, the terms or words used in the specification and claims should not be interpreted in a conventional or lexical sense, and the inventor can appropriately define the concept of terms in order to best describe his or her invention. Based on the principle of being present, it should be interpreted as a meaning and a concept consistent with the technical idea of the waste ferrite grinding apparatus according to an embodiment.

Therefore, the embodiments shown in the embodiments and drawings described herein are only the most preferred embodiment of the waste ferrite grinding apparatus according to one embodiment, and represent all of the technical ideas of the waste ferrite grinding apparatus according to an embodiment. It should be understood that there may be various equivalents and modifications that can replace them at the time of application.

1 and 2 show a waste ferrite pulverizing apparatus of a waste ferrite regeneration system according to an embodiment, and FIG. 3 shows a waste ferrite regeneration system according to an embodiment. 4 and 5 show a waste ferrite sorting apparatus of a waste ferrite regeneration system according to an embodiment.

1 and 2, the waste ferrite crushing apparatus 100 according to an embodiment includes a supply unit 110 for supplying waste ferrite, a crushing unit 120 for pulverizing waste parrite provided from the supply unit, and pulverized waste ferrite It includes a dust collecting part 140 for collecting dust from the powder and an exhaust part 150 for discharging the air from which the dust has been removed into the atmosphere, and the dust collecting part is disposed above the dust collecting part to filter dust from the pulverized waste light. 141 and a discharge element 142 disposed under the dust collecting part to discharge the dust-removed waste ferrite powder.

In addition, the waste ferrite crushing apparatus 100 is disposed between the crushing unit 120 and the dust collecting unit 140, and transfers the pulverized waste ferrite powder to the dust collecting unit, from the first transfer unit 130 and the discharge element of the dust collecting unit. An extended and pulverized waste ferrite powder may include a second transfer unit 160 that transfers the waste ferrite powder to the outside. Accordingly, the waste ferrite powder pulverized by the second transfer unit can be automatically transferred to the waste ferrite sorting device, which will be described later.

The crushing unit 120 may have a structure including a rotating blade, and through the pulverizing action through rotation of the rotating blade, the injected waste ferrite may be mechanically / physically crushed. However, the structure of the crushing unit 120 may include a structure of a conventional crushing device having various structures.

At this time, between the filter element 141 and the discharge element 142 of the dust collecting portion is disposed a guide that decreases in width as it progresses from the upper side to the lower side, and one end of the first transfer portion 130 is disposed on the upper surface of the crushing portion , The other end of the first transfer part may be disposed on one side of the guide.

In addition, the exhaust unit 150, a bypass path (not shown) extending from one side of the exhaust unit and connected to the filter element, is disposed inside the exhaust unit, and a first sensor element measuring the degree of contamination of air flowing through the exhaust unit ( Not shown), a first control element (not shown) and an exhaust portion that flows the total amount of air flowing through the exhaust portion toward the filter element side of the dust collecting portion when the degree of contamination of the air measured by the first sensor element exceeds a predetermined value. A first blocking element (not shown) that may be hinged and disposed at one end of the bypass path connected to one side may be further included.

Accordingly, the first control element may selectively block the main path of the exhaust portion or the bypass path by hinged the first blocking element.

That is, through such a configuration, the waste ferrite pulverizing apparatus discharges air to the outside of the apparatus only when the degree of contamination of air discharged from the process of pulverizing the waste perlite is recovered to a certain level, and if not, it continuously reminds the air. The possibility of environmental pollution can be reduced by purifying the filter element side of the dust collecting unit.

In addition, the crushing unit is disposed inside the crushing unit, a second sensor element (not shown) for measuring the size of the pulverized waste ferrite powder, a second blocking capable of selectively opening and closing the path between the crushing unit and the first transfer unit It may include a second control element (not shown) for controlling the operation of the second blocking element based on the value measured by the element (not shown) and the second sensor element.

Accordingly, the second control element, when the size of the pulverized waste ferrite powder measured by the second sensor element is smaller than a predetermined value, opens a path between the crushing portion and the first transfer portion, and the second sensor element. When the size of the pulverized waste ferrite granulated material measured by the above is more than a preset value, the path between the crushing unit and the first transfer unit is blocked by the second blocking element, so that the waste ferrite granular material that has not been crushed to a certain level is transferred to the first transfer unit. It can be prevented from being moved.

The waste ferrite pulverizing apparatus including such a configuration can effectively pulverize the waste ferrite and effectively prevent pollution from being generated by dust that may be generated in the pulverizing process. In addition, the waste ferrite crushing device may form a pulverized product having a certain level of uniformity.

Referring to FIG. 3, a waste ferrite regeneration system including a waste ferrite pulverizing apparatus may include a waste ferrite sorting apparatus disposed on the outside of the waste ferrite pulverizing apparatus and capable of sorting waste ferrite granules by size.

That is, the waste ferrite powder pulverized by the second transfer part of the waste ferrite crushing apparatus may be classified according to size after being transferred to the waste ferrite sorting apparatus.

Specifically, referring to FIGS. 4 and 5, the waste ferrite sorting apparatus according to an embodiment includes a sorting unit 210 for classifying the pulverized waste ferrite powder according to size, a support unit 220 for supporting the sorting unit, It is disposed on one side of the sorting unit and includes a vibration generating unit 230 for providing vibration on the sorting unit and a plurality of receiving units 240 and 250 for receiving the selected waste ferrite powders, respectively, according to the size. The ferrite powder may be classified according to size while being moved from one side to the other side of the classification unit by vibration generated by the vibration generation unit.

Specifically, the sorting unit 210 includes a base extending from one side to the other and an upper surface of the base to transmit the waste ferrite powder to the inside of the base, and the sorting unit may be divided into a plurality of sections. have.

As an example, it may be composed of a provision section 211 in which a waste ferrite powder is provided from an upper portion of one side of the classification section, a first section 212 disposed on one side of the classification section, and a second section 213 disposed on the other side of the classification section. You can.

At this time, the size of the micro-holes of the first transmissive element forming the first compartment may be smaller than the size of the micro-holes of the second transmissive element forming the second compartment.

Further, the height of one end of the sorting unit may be formed to be higher than the height of the other end of the sorting unit.

In addition, the first receiving portion 240 is disposed on the lower side of the first compartment to accommodate the waste ferrite powder transmitted through the first compartment of the sorting portion, and the second receiving portion 250 is disposed on the lower side of the second compartment. The waste ferrite granules transmitted through the second compartment are accommodated, and at the other end of the sorter, the waste ferrite granules that are not permeable in the first compartment and the second compartment of the sorter may be discharged.

The vibration generating units may be disposed on both sides of the sorting unit, and the upper ends of the vibration generating units may be disposed to incline toward the first section of the sorting unit based on an axis perpendicular to the ground, and an elastic unit may be disposed between the sorting unit and the support unit.

In addition, in the first section of the sorting section, a waste ferrite powder having a size of less than 0.5 mm is transmitted, and in the second section of the sorting section, a waste ferrite powder having a size of 0.5 mm or more and a size of 1.0 mm or less is transmitted, and at the other end of the sorting section. Waste ferrite granules with a size greater than 1.0 mm may be discharged.

In addition, the sorting unit further includes a rail (not shown) extending along the edges of both sides of the base and a blocking element (not shown) capable of selectively opening and closing the upper side of the sorting unit by being connected to the rail and hinged relative to one end. It can contain.

At this time, the blocking element is formed in a "b" shape, and when the waste ferrite sorting device is operated, the closed ferrite granules present on the upper surface of the sorting section by vibrations transmitted to the sorting section by closing the upper side of the sorting section. It can prevent scattering to the outside of the waste ferrite sorting apparatus.

As described above, in the embodiments, the embodiments have been described by specific matters such as specific components, etc., and with limited embodiments and drawings, which are provided for overall understanding. In addition, the present invention is not limited to the above-described embodiments, and those skilled in the art to which the present invention pertains can make various modifications and variations from these descriptions. Therefore, the spirit of the present invention is not limited to the above-described embodiments, and should not be determined. It will be said that not only the claims described below, but also those with equivalent or equivalent modifications to the claims are within the scope of the spirit of the present invention.

100: waste ferrite grinding device
110: supply unit
120: grinding unit
130: first transfer unit
140: dust collection unit
150: exhaust
160: second transfer unit

Claims (5)

Supply unit for supplying the waste ferrite;
A pulverization unit for pulverizing the waste parite provided from the supply unit;
A dust collecting part collecting dust from the pulverized waste ferrite powder;
An exhaust unit for discharging the air from which the dust has been removed into the atmosphere; And
A first transfer part disposed between the crushing part and the dust collecting part to transfer the pulverized waste ferrite powder to the dust collecting part;
Including,
The dust collecting unit,
A filter element disposed on an upper side of the dust collecting part to filter dust from the pulverized waste ferrite; And
A discharging element disposed under the dust collecting part to discharge the dusted waste ferrite powder;
Including,
The crushing unit,
A second sensor element disposed inside the crushing unit to measure the size of the pulverized waste ferrite powder;
A second blocking element capable of selectively opening and closing a path between the crushing portion and the first transfer portion; And
A second control element that controls the operation of the second blocking element based on the value measured by the second sensor element;
Including,
The second control element, when the size of the pulverized waste ferrite powder measured by the second sensor element is smaller than a preset value, opens a path between the crushing unit and the first transfer unit, and the second sensor When the size of the pulverized waste ferrite powder measured by the element is greater than or equal to a preset value, the waste ferrite not crushed to a predetermined level by blocking the path between the crushing part and the first transfer part by the second blocking element. The powder can be prevented from being moved to the first transfer unit,
Waste ferrite grinding device.
According to claim 1,
A second transfer part extending from one side of the discharge element of the dust collecting part to pulverized waste ferrite powder to the outside of the waste ferrite crushing apparatus;
Further comprising,
Between the filter element and the discharge element of the dust collecting portion is disposed a guide that decreases in width as it progresses from the upper side to the lower side,
One end of the first transfer portion is disposed on the upper surface of the crushing portion, the other end of the first transfer portion is disposed on one side of the guide,
Waste ferrite grinding device.
According to claim 2,
The exhaust portion,
A bypass path extending from one side of the exhaust portion and connected to the filter element;
A first sensor element disposed inside the exhaust portion to measure the degree of contamination of air flowing through the exhaust portion; And
A first control element that flows the entire amount of air flowing through the exhaust portion to the dust collecting portion when the degree of contamination of air measured by the first sensor element exceeds a predetermined numerical value;
Containing,
Waste ferrite grinding device.
According to claim 3,
The exhaust portion,
A first blocking element disposed on one end of the bypass path connected to one side of the exhaust portion and hingeable;
Further comprising,
The first control element is capable of selectively blocking the main path of the exhaust or blocking the bypass path by hinged the first blocking element,
Waste ferrite grinding device.
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