KR20050011649A - Pulverizer - Google Patents

Abstract

PURPOSE: A pulverizer is provided to allow the high-speed rotation in the state of a low noise, to control the rotation speed of a driving motor according to the sample, and to select a proper cooling method by detecting the temperature inside the rotating drum. CONSTITUTION: The pulverizer includes: a rotating body(104), having more than at least one cylindrical container of a determined size in the circumferential direction and a rotation axis(102) which is downwards-projected from the lower center; a cylindrical rotation drum(106), contained in the cylindrical container so as to be freely rotated according to the rotating body(104), and having an opening portion which is opened and shuttered by a rotation cap(105); more than at least one steel ball(101), inserted into the rotating drum(106) so as to pulverize the sample; a body portion(108), containing the rotating body(104) and having an axial hole; a driving motor(112), whose driving pulley(111) is axially installed on a driving axis; and a cooling unit.

Description

Pulverizer

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a finely divided mill, and more particularly, to a finely divided mill which can be widely used for crushing foodstuffs or industrial raw materials in the pharmaceutical raw materials or food manufacturing processing industry.

In general, most of the conventional grinding mill is installed a plurality of grinding wheels or rollers horizontally, by rotating the grinding wheel or roller to be ground by the ground friction force by the difference in the rotational speed.

However, the above-mentioned conventional pulverizer has a relatively short time for receiving the crushing force by being ground to a crushing plate or a crushing roller, so that the resolution is low and many times the pulverization must be repeated repeatedly. As a result, the grinding effect was not lower than expected and fine grinding was not achieved.

Therefore, the pharmaceutical industry or the non-metallic mineral manufacturing industry is required to develop a pulverizer to produce a finer or finer fine powder than the present.

In addition, in the case of pulverizing the sample by the pulverizer, the frictional heat is generated by the friction of the pulverization tool and the sample during the pulverization, and the sample may be deteriorated while being micronized according to the sample. This happens.

The present invention devised to solve the above-mentioned demands and problems, to minimize the heat generation of the grinding tool to prevent the deterioration of the sample and at the same time to achieve high-speed rotation at low noise and high-differentiation of the sample. In addition, it provides the purpose to control the rotational speed of the drive motor according to the sample, and to select the appropriate cooling method by sensing the temperature inside the rotor.

1 is an exploded perspective view showing the structure of the first embodiment of the present invention.

Fig. 2 is a sectional view showing the structure of the first embodiment of the present invention.

Figure 3 is a plan sectional view showing the structure of the first embodiment of the present invention.

Figure 4 is an overall perspective view showing the appearance of the second embodiment of the present invention.

Figure 5 is an exploded perspective view showing the internal structure of the body of the second embodiment of the present invention.

Figure 6a is a cross-sectional view showing a coupling state of the second embodiment of the present invention.

Figure 6b, Figure 6c is a cross-sectional view showing a state in which the rotating cylinder is inserted / coupled in the body of the second embodiment of the present invention.

FIG. 7 is a cross-sectional view taken along the line A-A of FIG. 6A; FIG.

8 is a control block diagram of a second embodiment of the present invention;

9 is a view showing an embodiment of a rotating cylinder of the second embodiment of the present invention.

<Description of the symbols for the main parts of the drawings>

101: steel ball 102: rotation axis

103: accommodating part 104: rotating body

105: rotating cap 106: rotating cylinder

107: shaft hole 108: body

109: interlock pulley 110: belt

111: drive pulley 112: drive motor

113: hollow part 114: flow path

115: piping 116: drain hole

117: cooling groove 118: bearing

119: opening and closing plate 132: fixed plate

136: rotating member 140: planetary gear

141: planetary body 142: internal gear

145: rotating disk 146: third hole

148: stopper 151: ball caster

153: heat detection hole 155: infrared sensor

158: cooling hole 159: discharge hole

The above object is, at least one cylindrical receiving portion 103 of a predetermined size is formed in the circumferential direction, the rotating body 104 having a rotating shaft 102 protrudes downward from the lower center; A cylindrical rotary cylinder 106 accommodated in the receiving portion 103 and freely rotating according to the rotation of the rotating body 104, and the opening is opened and closed by the rotating cap 105; At least one steel ball 101 inserted into the rotary tube 106 to crush the sample; In the state in which the rotating cylinder 106 is accommodated in the accommodating part 103, the outer cylinder accommodates the rotating body 104 so as to be freely rotated according to the rotation of the rotating body 104, and the shaft hole is formed so that the rotating shaft 102 penetrates downward. A body 108 in which 107 is formed; A drive motor 112 in which a drive pulley 111 connected to the belt 110 is connected to a linkage pulley 109 arranged at a lower end of the rotary shaft 102 and is arranged on a drive shaft; It is achieved by a grinding mill, characterized in that it comprises cooling means for the rotating body to cool the rotating body 104 rotating in the body (108).

Here, the cooling means of the rotating body, the hollow portion 113 formed inside the rotating shaft 102; At least one flow passage 114 formed at a predetermined position on the hollow portion 113 and connected to the accommodation portion 103; A cooling water supply device (not shown) configured to supply cooling water to a pipe 115 to which the rotating shaft 102 is rotatably coupled at a lower end of the rotating shaft 102; A drain hole 116 is formed below the body 108 to drain the supplied cooling water.

In addition, it is preferable to further include a cooling groove 117 of a predetermined width formed on the inner diameter surface of the receiving portion (103).

On the other hand, the above object is provided with a receiving space of a predetermined size, the upper end is bolted and coupled with the opening and closing plate 119, the fixing plate 132 and the lower end is bolted coupled to the upper portion of the base 131 of a predetermined height Body 108 is provided with an opening and closing door 133 of a predetermined size on the outer diameter surface; A rotating shaft 102 inserted into the first and second through holes 134 and 135 vertically penetrating the base 131 and the fixing plate 132 and inserted into the body 108; A rotating member 136 rotating in accordance with the rotation of the rotating shaft 102 under the rotating shaft 102 inside the body 108; A driving motor 112 connected to the interlocking pulley and the belt 110 arranged at the lower end of the rotating shaft 102, the driving motor 112 installed at the lower portion of the base 131; At the same time as the rotating member 136 rotates and rotates around the rotating shaft 102 at the same time, there is provided a receiving space of a predetermined size for receiving a sample and a plurality of steel balls 101 for crushing the sample therein. A rotary cylinder 106 opened and closed by the rotary cap 105; In addition to the rotation of the rotary member 136 is achieved by a grinding mill characterized in that it comprises a rotating means of the rotating cylinder to rotate about the rotating shaft 102 while rotating the rotary cylinder 106.

Here, the rotating means of the rotating cylinder, a plurality of rotating holes 137 formed in the circumferential direction around the rotating shaft 102; The planetary body 141 having the planetary gear 140 wound around the outer diameter surface of the linking unit 139 protruding to the upper end of the rotating member 136 while the rotating unit 138 is inserted to freely rotate in the rotating hole 137. )Wow; An internal gear 142 coupled to the inner diameter surface of the body 108 such that the planetary gear 140 is engaged and revolves about the rotation shaft 102; It is preferable to include a fixing means of the rotating cylinder for coupling the rotating cylinder 106 to the planetary body (141).

And, the fixing means of the rotating cylinder, the polygonal fixing groove 143 formed on the planetary body 141 and; A fixing protrusion 144 protruding in a polygon to correspond to the fixing groove 143 at the bottom of the rotating cylinder 106; A position corresponding to the center of the rotating cylinder 106 fixed to the rotating member 136 is formed in the circumferential direction around the rotating shaft 102 in the rotating disk 145 which is arranged at a predetermined position of the upper portion of the rotating shaft 102. A third through hole 146 formed in each; A long hole 147 having a predetermined length relatively smaller than the third through hole 146 and formed to cross the third through hole 146; The stopper 148, which is relatively smaller than the long hole 147, protrudes in the direction of the long hole 147 on the outer diameter surface thereof so as to be disposed below the third through hole 146, and a protrusion 149a protruding upward from the rotating disc 145. The elastic member 150 is installed between the heads 149b of the upper end, and the ball caster 151 is installed at the lower end thereof so that the upper end of the rotating cap 105 of the rotating cylinder 106 is provided by the elastic force of the elastic member 150. And a detachable member 149 to be pressed downward or detached.

And, it is preferable to further include a spherical rotary groove 152 formed at the center point of the rotary cap 105 of the rotary cylinder 106, the heat formed in the center of any one of the rotary cap 105 of the rotary cylinder 106 Paper hole 153; Is inserted into any one of the third through hole 146 of the rotating disc 145 to be disposed on the vertical upper portion of the heat sensing hole 153 is fixed to the bracket 154 attached to the bottom of the rotating disc 145, the heat sensing hole 153 Infrared sensor 155 for sensing the temperature inside the rotating tube 106 through; And a first operation unit 157 electrically connected to the infrared sensor 155 to convert an electrical signal received from the infrared sensor 155 into a temperature value and display the same on the first display unit 156 of the base 131. It is desirable to.

In addition, at least one cooling hole 158 formed to penetrate the inside of the body 108 at a predetermined position of the body 108; A cooling device 171 coupled to the cooling hole 158 to spray at least one of air and cooling water; It further includes a discharge hole 159 perpendicular to the fixing plate 132 of the body 108.

A comparison unit 161 connected to the first operation unit 157 and comparing the temperature sensed by the infrared sensor 155 with a preset temperature stored in the memory unit 160; It is preferable to further include a controller 162 connected to the comparator 161 to control the cooling device 171 so that at least one of air and cooling water is injected when a predetermined signal is applied. .

In addition, the slit disc 163 is arranged on the lower end of the rotary shaft 102, the plurality of slits 163a is formed in the circumferential direction; A detection unit 164 installed on the slit 163a of the slit disc 163 and disposed below the light emitting unit 164a and the light receiving unit 164b to detect the rotational speed of the rotating shaft 102; The rotational speed is calculated from the second operation unit 165 that calculates the rotational speed of the planetary gear 140 by multiplying the gear teeth ratio of the planetary gear 140 by the rotational speed per minute of the driving motor 112 detected by the detection unit 164. It further includes a second display unit 166 to be displayed.

Then, the motor is electrically connected to the drive motor 112 to control the rotational speed of the drive motor 112 according to the input numerical value when the user inputs a predetermined key of the key input unit 167 to set the rotational speed An injection valve 169 further including a control unit 168 and installed at a predetermined position of the rotary cylinder 106 and the rotary cap 105 and connected to an injection tube for injecting a predetermined liquid material; It is preferable to further include a check valve 170 which is installed at a predetermined position of the rotating cylinder 106, the opening of the valve so that the internal pressure is discharged when the pressure inside the rotating cylinder 106 rises to a predetermined size. Do.

The configuration and operation of the present invention described above will be described separately by embodiment, but first, the first embodiment according to the present invention will be described with reference to FIGS. 1 to 3 as follows.

First, as shown in FIG. 1, the body 108 has a cylindrical shape, and a drain hole 116 is formed at a lower predetermined position so as to penetrate an inner and an outer diameter thereof.

And, the lower portion of the body 108 is formed with a shaft hole 107 so that the rotary shaft 102 is inserted into the lower end of the rotating body 104 accommodated in the body 108, the rotary shaft for smooth rotation of the shaft 102 The bearing 118 is externally or contracted on the 102, and the upper end of the body 108 allows the opening and closing plate 119 to be opened and closed so that the rotating cylinder 106 may be detached from the receiving portion 103 or rotated below when rotating. It is desirable to prevent the coolant to be leaked out of the body 108.

As shown in the figure, a plurality of cylindrical receiving portions 103 are formed around the rotating shaft 102 as shown, and the receiving portions 103 may accommodate the cylindrical rotating cylinders 106. The cylindrical shaft 113 has a hollow portion 113 for guiding the cooling water supplied from the cooling water supply device (not shown) to be described below from the lower end to the inside of the rotating body 104.

In addition, at a predetermined position of the hollow portion 113 extending to the inside of the rotating body 104, a plurality of flow passages 114 are formed to extend to the inner diameter surface of the receiving portion 103, the cooling water supplied to the receiving portion 103 Allow for even delivery.

Here, the inner diameter surface of the accommodating part 103 is a cooling groove 117 of a predetermined width is formed as shown in Figures 1 to 2 to minimize the friction area between the rotating cylinder 106 and the accommodating part 103. In addition, it is preferable to allow the cooling water supplied to be in wide contact with the outer diameter surface of the rotating cylinder 106.

On the other hand, a plurality of steel balls 101 of a predetermined size are inserted into the rotating cylinder 106, the steel balls 101 are connected to the drive pulley 111 by the rotation of the drive motor 112 belt 110 When the rotating body 104 is rotated by rotating the interlocking pulley 109 arranged on the lower end of the rotating shaft 102, the rotating cylinder 106 rotates and rotates with each other by the centrifugal force to the rotating cylinder 106 in the process of hitting. Grind the sample to be inserted.

According to the present invention having the above-described configuration, as the rotating shaft 102 is rotated by the drive motor 112 as shown in FIG. 3, the plurality of rotating cylinders 106 come into contact with the inner diameter surface of the body 108. When the rotary cylinder 106 has four as shown in FIG. 3, the rotary cylinder 106 has an inner diameter about 1/4 times smaller than the diameter of the rotary body 104, and thus the rotational speed is accelerated to about four times. According to this rotation, the steel ball 101 accommodated in the rotary cylinder 106 is centrifugal force, rotational acceleration, the impact force of the inner surface of the rotary cylinder 106 and the steel ball 101, shear stress according to the rotation, between the steel ball 101 The impact force acts together and is applied to the sample received in the rotating cylinder 106.

Therefore, such a force and impact force can be pulverized the sample to a size smaller than the size of the gap between the steel ball 101 and the steel ball 101 to be able to produce a high fine powder in a short time.

On the other hand, the rotary force and the impact force and frictional force ultimately generates the rotary cylinder 106 and the body 108, this heat generated as shown in Figure 2 pipe 115 connected to the lower end of the rotary shaft 102 When the cooling water supply device connected to the pipe 115 supplies cooling water through the cooling water, the cooling water is guided upward along the hollow portion 113 of the rotating shaft 102 and the plurality of flow passages 114 formed in the hollow portion 113. 2 is injected into the inner diameter surface side of the receiving portion 103 as shown in FIG.

Therefore, since the frictional heat is attenuated by the coolant in the rotary cylinder 106 rotating in the accommodating part 103, and the inner diameter surface of the accommodating part 103 is formed with a cooling groove 117 having a predetermined width as shown. The coolant supplied through the flow passage 114 flows along the flow passage 114 in the rotational direction while contacting the rotary cylinder 106 and flows downwardly, and the coolant flowed into the lower portion of the body 108 is drained through the drain hole 116. It is discharged to outside through).

On the other hand, the cooling water supply apparatus according to the present invention is to pump the cooling water to supply to the pipe 115, in the present invention may collect and re-pump the cooling water discharged to the drain hole 116 again in the present invention. It is not limited.

On the other hand, the second embodiment according to the present invention will be described with reference to the accompanying drawings 4 to 9 as follows.

As shown in FIG. 4, a fixing plate 132 is assembled to an upper portion of the base 131 installed at a predetermined height, and a lower end of the cylindrical body 108 is bolted to an upper portion of the fixing plate 132, and an opening and closing plate is formed on the upper end thereof. 119 is bolted.

Here, the opening and closing door 133 is installed in a predetermined position of the body 108, as shown in Figure 5 and 6 is configured to be opened and closed, the fixed plate 132 and the base ( Second and first holes 135 and 134 penetrating 131 are formed.

In addition, the rotation shaft 102 is inserted to penetrate the first and second through holes 134 and 135 and protrude inwardly of the body 108, and the interlocking pulley 109 is disposed at the lower end of the rotation shaft 102. Is installed and connected to each other by the belt 110 and the drive pulley 111 arranged on the drive shaft of the drive motor 112 installed below the base 131.

Therefore, the rotational force of the drive motor 112 is transmitted to the rotation shaft 102 through the drive shaft, the drive pulley 111, the interlocking pulley 109, wherein the rotation shaft 102 is the first, second through hole ( 134) to cool the rotating shaft 102 by inserting a bearing in the inner diameter surface of the second through hole 135 so as to be smoothly rotated, and the coolant to be described below by interpolating an oil seal After the water is injected into the body 108 to prevent the coolant leaks to the second through hole (135).

On the other hand, the rotating member 102 is arranged in the lower portion of the body 108, as shown in Figures 5 to 6 to rotate the rotating member 136, the rotating member 136 a plurality of rotating holes 137 toward the circumferential direction Is formed, and the planetary body 141 is inserted into each of the rotating holes 137 so as to be freely rotatable.

Here, the rotating part 138 of the planetary body 141 is inserted into the rotating hole 137, and the planetary gear 140 is wound around the outer diameter surface of the interlocking part 139 of the upper part, in particular, the rotating hole 137 The inner diameter of the bearing is interpolated so that the rotating part 138 can be smoothly rotated, and the oil seal is inserted into the upper portion of the rotating part 138 so as not to leak the coolant as described above.

In addition, an internal gear 142 is installed at a predetermined position of the inner surface of the body 108 to be engaged with the planetary gear 140 of the planetary body 141. When the rotating member 136 rotates, the internal gear 142 is inserted into the rotating hole 137. The planetary body 141 is rotated about the rotational axis 102 while being engaged with the internal gear 142 and rotates at the same time.

In addition, the fixing groove 143 is formed on the upper surface of the planetary body 141 at the bottom of the rotating cylinder 106 to form a fixed groove 143 of a predetermined depth of a polygon, and to receive a sample and a plurality of steel balls 101. By forming a fixing protrusion 144 of the polygon corresponding to the) so that the fixing protrusion 144 is unevenly coupled to the fixing groove 143.

Therefore, the rotating part 138 of the planetary body 141 is free to rotate (rotate) while rolling in contact with the bearing of the rotating hole 137, and thus, the rotary cylinder 106 is unevenly coupled to the upper end of the linkage 139. ) Is freely rotated integrally with the planetary body (141).

Here, the rotary cylinder 106 is combined with the rotary cap 105 is configured so that the sample and the plurality of steel balls 101 accommodated in the rotary cylinder 106 is not separated from the rotary cylinder 106, when rotating at high speed In order to prevent the fixing protrusion 144 of the rotating cylinder 106 from being detached from the fixing groove 143, as shown in FIG. 6, a rotating disc 145 is formed on the top of the rotating shaft 102, and the rotating disc is rotated. A plurality of third through holes 146 are formed through the same arrangement as that of the rotary cylinder 106 (ie, the plurality of third through holes 146 in the circumferential direction about the rotary shaft 102). The third through hole 146 is formed.)

Here, as shown in FIG. 5, a long hole 147 having a predetermined length facing the rotation shaft 102 is formed to cross the third through hole 146, and the inner diameter of the long hole 147 is the third through hole 146. It is preferable to form relatively small, and the removable member 149 is inserted into the third through hole 146 from the bottom to the top.

At this time, the elastic member 150 is installed in the protrusion 149a protruding to the upper portion of the third through hole 146, and the head 149b is fastened to the female screw formed at the upper end of the detachable member 149 to elastic. The member 150 is prevented from detaching from the detachable member 149.

On the other hand, the outer diameter of the detachable member 149 disposed below the third through hole 146 has a stopper 148 having a thickness enough to communicate with the long hole 147 protrudes in the long hole 147 direction. When the elastic member 150 elastically supports the head 149b, when the detachable member 149 tries to protrude upward from the third through hole 146, the stopper 148 is 90 ° in the direction of the long hole 147. When the detachable member 149 is rotated so that the stopper 148 interferes with the bottom of the third through hole 146, the protrusion is prevented.

At this time, the ball of the ball caster 151 formed at the lower end of the detachable member 149 is in close contact with the spherical rotary groove 152 formed in the center of the rotary cap 105 to press down the rotary cap 105, Even when the rotating cylinder 106 is to be prevented from shaking or detachment.

Here, at the bottom of the third through hole 146, a fixing groove 147a of a predetermined size is formed in the longitudinal direction in both directions that are 90 degrees with the long hole 147, so that the stopper 148 is formed in the fixing groove 147a. By inserting, it is preferable that the stopper 148 can always be maintained at 90 ° even at high speed rotation.

As described above, it is preferable to install detachable members 149 in the third through holes 146 of the rotating disc 145 so that the rotating cylinder 106 maintains stable rotation even at high speed. 5 and 6, the infrared sensor 155 is inserted into one of the two sides 146, and the infrared sensor 155 is fixed to the bracket 154 attached to the bottom of the rotating disc 145. .

In this case, a heat sensing hole 153 of a predetermined size is formed in the center of the rotating cap 105 of the rotating cylinder 106 disposed below the third through hole 146 into which the infrared sensor 155 is inserted. Infrared rays emitted from the 155 may be introduced into the rotating cylinder 106 through the heat sensing hole 153.

Accordingly, when the internal temperature of the rotating cylinder 106 is sensed and the signal is sent to the first operation unit 157, the first operation unit 157 converts the signal into a temperature value and the first display unit installed in the base 131 ( 156).

Here, the conductive wires connected to the infrared sensor 155 (not shown) are inserted into the conductive wire connecting hole 174 formed through the upper portion of the rotating disk 145 but penetrating from the upper portion to the upper portion of the rotating shaft 102 to the upper portion. The drawn conductors are connected to a conventional slip ring 172 and electrically connected to the first operation unit 157 as shown in FIG. 6.

Therefore, even when the rotation disc 145 is rotated, since the slip ring 172 is rotated and also electrically connected, the interference is not caused, such as twisting the conductor.

Meanwhile, at least one cooling hole 158 is formed at a predetermined position of the outer surface of the body 108 to penetrate the inside of the body 108, and the cooling hole 158 includes air and coolant. An injection nozzle (not shown) configured to inject any one of the water is coupled, and the cooling nozzle 171 is preferably connected to the injection nozzle.

Here, it is preferable to form two cooling holes 158 in the body 108 and combine the air jet nozzle (not shown) and the coolant jet nozzle (not shown), respectively, and the compressor (not shown) in the air jet nozzle (Not shown) can be connected to the coolant injection nozzle to selectively use the cooling method.

That is, the comparison unit 161 may compare the temperature inside the rotating cylinder 106 detected by being connected to the first operation unit 157 with a predetermined temperature previously stored in the memory unit 160, and according to the compared value. It is preferable that the controller 162 controls the cooling device 171 so that either air or cooling water can be injected.

In addition, a slit disc 163 in which a plurality of slits 163a are formed in the circumferential direction is formed at the lower end of the rotating shaft 102, and the light emitting part 164a and the light receiving part 164b are disposed above and below the slit 163a. The detection part 164 is provided so that each may be arrange | positioned.

As the rotating shaft 102 rotates, when the rotational speed of the rotating shaft 102 is detected as an electrical signal generated as the slit 163a passes between the light emitting unit 164a and the light receiving unit 164b, the second operation unit ( 165 calculates the rotational speed of the planetary gear 140 by multiplying the rotational speed of the rotational shaft 102 by the gear tooth ratio of the planetary gear 140 and displays the rotational speed of the planetary body 141 on the second display unit 166. Let's do it.

Here, the motor control unit 168 is electrically connected to the drive motor 112, the motor control unit 168 is connected to the key input unit 167, the user rotates the rotary shaft to operate the key input unit 167 When the rotation speed of the engine 102 is input, the rotation speed input to the third display unit 173 is displayed, and the input rotation speed is transmitted to the second operation unit 165 to calculate the rotation speed of the planetary body 141. In addition, the motor controller 168 controls the driving motor 112 to adjust the rotational speed of the rotating shaft 102 at the rotational speed of the input driving motor 112.

On the other hand, the rotary cap 105 of the rotary cylinder 106 is provided with an injection valve 169 to inject a predetermined liquid material into the rotary cylinder 106, and, furthermore, inside the rotary cylinder 106 When the pressure rises to a predetermined size, it is preferable to install a check valve 170 to open the valve so that the pressure inside the rotating cylinder 106 can be discharged to the outside so that the pressure can be automatically adjusted.

If described in more detail in Figure 4 to 9 the effect of the second embodiment of the present invention made of the above configuration as follows.

First, the user inserts the sample and the steel ball 101 inside the rotating cylinder 106, and then through the opening and closing door 133 in the closed state of the rotating cap 105 as shown in Figure 6b, 6c While inserting 106 into the body 108, the fixing protrusion 144 at the bottom of the rotating tube 106 is coupled to the recessed groove 143 of the upper portion of the planetary body 141 inserted into the rotating hole 137. .

Here, the removable member 149 of the rotary disk 145 is a state in which the stopper 148 is raised by a predetermined height by the elastic force of the elastic member 150 in the state inserted into the long hole 147, as described above After the tradition 106 is coupled to the planetary body 141, when the user directly grabs the ball caster 151 and pulls it downward, the elastic member 150 is compressed and the detachable member 149 is lowered.

At this time, if the stopper 148 is rotated after the detachable member 149 rotates to be 90 ° with the long hole 147, the detachable member 149 is elevated by the elastic restoring force of the elastic member 150, The detachable member 149 is interrupted by the stopper 148 at the bottom of the third through hole 146, so that it can no longer be lifted and stopped. Here, the stopper 148 is preferably inserted into the fixing recess 147a formed at the bottom of the third through hole 146 so that the stopper 148 does not move during rotation.

In addition, when withdrawing the rotary cylinder 106 from the inside of the body 108 to the outside, the stopper 148 coincides with the long hole 147, and the detachable member 149 is attached to the third through hole 146 by the elastic member 150. In this case, the stopper 148 is lifted while being inserted into the long hole 147 so that the ball caster 151 pressurizing the rotating cylinder 106 releases the rotating cylinder 106. The user lifts the rotary tube 106 slightly to release the fixing protrusion 144 from the fixing groove 143, and then withdraws the opening and closing door 133 as shown in FIGS. 6B and 6C.

After accommodating the rotating cylinder 106 in the body 108 as described above, the opening and closing door 133 is closed, and pressing the "Start" button of the control panel installed on the base 131, the drive motor 112 is activated to rotate the shaft 102 is rotated.

Meanwhile, as shown in FIG. 9, liquid nitrogen may be injected into the rotary cylinder 106 according to the material of the sample. For example, a soft sample (placenta, etc.) may be put into the rotary cylinder 106 and then powderized. If the sample is difficult to be powdered properly, the liquid nitrogen is injected into the injection valve 169 so that the soft sample is instantaneously cooled and then collided with the steel ball 101 so as to be finely powdered. It is preferable that the injection valve 169 and the check valve 170 are conventional and are schematically illustrated.

Here, in the process of pulverizing the soft sample while the rotary cylinder 106 rotates, as well as an increase in temperature, the internal pressure may be increased. Accordingly, when the rotary cap 105 is opened, the user may be injured. Since there is a concern, when the internal pressure rises to a certain level, it is preferable that the check valve is automatically opened by internal pressure so that the internal pressure can be discharged.

On the other hand, when the user inputs the rotational speed (speed per minute, rpm) of the rotary shaft 102 through the key input unit 167 of the control panel installed on the base 131, and press the "Start" button, shown in Figure 8 As described above, the motor control unit 168 applies power to the driving motor 112 to rotate and simultaneously control the rotation speed.

Therefore, the rotation of the drive pulley 111 of the drive shaft is transmitted to the interlocking pulley 109 of the rotary shaft 102 through the belt 110, and, as a result, the rotary shaft 102 rotates and rotates to the rotary shaft 102 at the same time. The rotary member 136 is arranged to rotate, and the rotary disk 145 built on the rotary shaft 102 also rotates at the same speed as shown in Figure 6a.

Here, the detection unit 164 detects the rotational speed of the rotary shaft 102 on the upper and lower portions of the slit disc 163, and the second operation unit 165 is the rotational speed (rpm) and the internal gear ( The rotational speed of the planetary body 141 is calculated by multiplying the number of teeth of the planetary body 140 by the number of teeth of the planetary body 142 according to the number of teeth of the planetary body 141. 166).

That is, when the internal gear 142 and the planetary gear 140 are 1: 3, if the rotational speed of the rotational shaft 102 is 100, the rotational speed per minute (100) x the number of teeth of the planetary gear 140 (3) = 300rpm It is displayed on the second display unit 166.

Therefore, the user can selectively powder the sample stably by adjusting the rotation speed of the planetary body 141 according to the sample accommodated in the rotary cylinder 106.

On the other hand, when the rotating member 136 is rotated by the rotation of the rotary shaft 102, the planetary body 141 inserted into the rotary hole 137 is revolving around the rotary shaft 102 as shown in FIG. Since the planetary gear 140 of 141 is engaged with the internal gear 142, the planetary gear 140 rotates in the rotation hole 137.

At this time, the rotating part 138 is rotated while rolling contact with the bearing of the rotary hole 137, the rotating cylinder coupled to the planetary body 141 by the fixing groove 143 and the fixing protrusion 144 of the planetary body 141 ( 106 performs the revolution and rotation at the same time and the same speed as the planetary body 141.

Here, the rotary cylinder 106 can be stably rotated without deviating from the rule because the ball caster 151 of the detachable member 149 is pressed downward in the upper portion of the rotary cap 105.

In addition, as described in the first embodiment, the sample and the steel ball 101 collide with each other in the rotating cylinder 106 to differentiate the sample.

In this case, when the internal temperature of the rotary cylinder 106 rises, the material change or the effect of the material may decrease depending on the sample. As shown in FIG. 6A, the infrared sensor 155 rotates the cap 105. The infrared ray is emitted into the rotating cylinder 106 through the heat sensing hole 153 of the) and the temperature is sensed in the rotating cylinder 106 to transmit a signal to the first calculation unit 157. ) Displays the internal temperature of the current rotating cylinder 106 on the first display unit 156 according to the received signal so that the user can recognize the current internal temperature.

In addition, the comparison unit 161 connected to the first operation unit 157 and receiving the internal temperature of the rotating cylinder 106 from the first operation unit 157 may receive a predetermined temperature previously stored in the memory unit 160. Compare the internal temperature of the rotary cylinder 106 and, if the internal temperature is above a predetermined temperature, send a signal to the controller 162 to control the air compressor (not shown) connected to the air jet nozzle (not shown). To operate to inject air into the body 108 or to operate a coolant supply device (not shown) connected to a coolant injection nozzle (not shown) to inject coolant into the body 108. These selections may be set in advance according to a user's selection or a sample, and may be selectively sprayed according to the degree of increase in the temperature inside the rotating cylinder 106. The present invention is not limited thereto. Not The.

As described above, after the air or coolant is injected, it is discharged to the discharge hole 159 formed in the fixed plate 132 while rotating together with the rotary cylinder 106 and the rotary member 136 in the body 108. Accordingly, the internal temperature of the rotating cylinder 106 is also lowered.

On the other hand, when a predetermined time is input from the key input unit 167 to set the driving time of the drive motor 112, the input time is displayed so that the remaining time of the drive motor 112 is displayed on the time display unit 176. After the driving motor 112 is operated according to the input time and the timer 175 is operated for the remaining time, the motor controller 169 may control the driving motor 112.

Therefore, it is preferable to set an appropriate time according to the sample to be differentiated, and to allow the sample to be differentiated in the rotary cylinder 106 by that time, thereby preventing excessive driving of the device in advance.

As described above, in the present invention, the centrifugal force of the rotating body and the rotating acceleration force of the rotating cylinder, the impact force between the rotating cylinder and the steel section, and the shearing force, the impact force of the steel section, are combined, and the crushing force is applied to the sample. In addition, it enables high micronization of the sample and prevents heat generated by such rotational and frictional forces due to continuous supply of cooling water so that the sample is not deteriorated by heat or the grinding tool is not affected by this high heat. Has the effect of enabling

Claims (13)

At least one cylindrical receiving portion having a predetermined size formed in a circumferential direction and having a rotating shaft projecting downward from the lower center; A cylindrical rotary tube accommodated in the receiving part and freely rotating according to the rotation of the rotating body, and the opening is opened and closed by the rotating cap; At least one steel ball inserted into the rotary tube to crush the sample; A body which externally accommodates the rotating body so that the rotating cylinder can be freely rotated according to the rotation of the rotating body in the state accommodated in the accommodating part, and the shaft hole is formed so that the rotating shaft passes therethrough; A drive motor in which a driving pulley connected to a belt is interlocked on a lower end of the rotary shaft by a drive shaft; And a cooling means of the rotating body to cool the rotating body rotating in the body. The method of claim 1, Cooling means of the rotating body, A hollow portion formed inside the rotation shaft; At least one flow path formed at a predetermined position on the hollow part and connected to a receiving part; A cooling water supply device configured to supply cooling water to a pipe having a rotating shaft rotatably coupled at a lower end of the rotating shaft; And a drain hole formed in the lower portion of the body to drain the supplied cooling water. The method of claim 1, And a cooling groove having a predetermined width formed on an inner diameter surface of the receiving portion. A receiving space having a predetermined size is provided, and an upper end is coupled to the opening and closing plate, and a fixed plate and a lower end are coupled to and fixed to the upper part of the base at a predetermined height, and a body having an opening and closing door of a predetermined size is installed on the outer diameter surface; A rotating shaft inserted into the first and second through holes vertically penetrating the base and the fixing plate and inserted into the body; A rotating member rotating in accordance with the rotation of the rotating shaft under the rotating shaft inside the body; A drive motor installed at a lower portion of the base, the drive pulley connected to the interlocking pulley and the belt formed at the lower end of the rotating shaft being arranged on the drive shaft; A rotating tube provided with a predetermined size accommodating space accommodating a rotating shaft and rotating at the same time as the rotating member and rotating around the rotating member and accommodating a sample and a plurality of steel balls for crushing the sample therein; And a rotating means of the rotating cylinder which rotates the rotating cylinder together with the rotation of the rotating member and revolves about the rotating shaft. The method of claim 4, wherein Rotating means of the rotating cylinder, A plurality of rotating balls formed in a circumferential direction about the rotating shaft; A planetary body in which a planetary gear is wound on an outer diameter surface of the linking unit which is inserted into the rotating unit so as to be freely rotated in the rotating hole and protrudes toward the upper end of the rotating member; An internal gear coupled to an inner diameter surface of the body such that the planetary gear is engaged and revolves about a rotation axis; And a grinding means for fixing the rotary cylinder to the planetary body. The method of claim 5, The fixing means of the rotating cylinder, A polygonal fixing groove formed on the planetary body; A fixing protrusion protruding in a polygonal shape so as to correspond to a fixing groove at a bottom of the rotating tube; A third through hole formed in a circumferential direction around the rotating shaft in a rotating disk arranged at an upper predetermined position of the rotating shaft, the third through hole being formed at a position corresponding to the center of the rotating cylinder fixed to the rotating member; A long hole having a predetermined length relatively smaller than the third through hole and formed to cross the third through hole; A stopper relatively smaller than the long hole is projected on the outer diameter surface in the long hole so as to be disposed below the third through hole, and the elastic member is installed between the protrusion and the head of the upper end protruding from the upper portion of the rotating disc, and a ball caster is installed at the bottom. And a detachable member for pressing down or detaching the upper end of the rotary cap of the rotary tube by the elastic force of the elastic member. The method of claim 4, wherein And a spherical rotary groove formed at the center of the rotating cap of the rotary cylinder. The method of claim 4, wherein A heat sensing hole formed at the center of one of the rotating caps of the rotating cylinder; An infrared sensor inserted into one of the third through holes of the rotating disc so as to be disposed on the vertical upper portion of the heat sensing hole and fixed to a bracket attached to the bottom of the rotating disc, and sensing a temperature inside the rotating tube through the heat sensing hole; And a first calculation unit electrically connected to the infrared sensor and converting an electrical signal received from the infrared sensor into a temperature value and displaying the first signal on the first display unit of the base. The method of claim 4, wherein At least one cooling hole formed to penetrate the inside of the body at a predetermined position of the body; A cooling device coupled to the cooling hole to spray at least one of air and cooling water; And a discharge hole penetrated perpendicularly to the fixed plate of the body. The method according to claim 8 or 9, A comparison unit connected to the first operation unit and comparing the temperature sensed by the infrared sensor with a preset temperature stored in the memory unit; And a controller for controlling the cooling device such that at least one of air and cooling water is injected when the predetermined signal is connected to the comparison unit. The method of claim 4, wherein A slit disc arranged at a lower end of the rotating shaft and having a plurality of slits formed in a circumferential direction; A detector configured to detect the number of rotations of the rotating shaft by installing the light emitting part and the light receiving part on the slit of the slit disc; And a second display unit configured to display the rotational speed from the second calculation unit which calculates the rotational speed of the planetary gear by multiplying the revolutions per minute of the driving motor detected by the detection unit by the gear tooth ratio of the planetary gear. grinder. The method of claim 4, wherein And a motor control unit electrically connected to the driving motor to control the rotation speed of the driving motor according to the input numerical value when the user inputs a predetermined key of the key input unit to set the rotation speed. . The method of claim 4, wherein An injection valve installed at a predetermined position of the rotary cylinder rotary cap and connected to an injection tube for injecting a predetermined liquid material; And a check valve installed at a predetermined position of the rotary cylinder rotating cap to open the valve to discharge the internal pressure when the pressure inside the rotary cylinder rises to a predetermined size.