KR101113819B1 - Silo Apparatus - Google Patents

Abstract

The present invention relates to a siro apparatus, comprising a sieve (110) and a sieve (110) having an inlet portion (111) into which the mixed cement is introduced, and an outlet portion (112) communicating with the inlet portion (111) and narrowing in diameter. The main body 110 having a storage unit 130 in communication with the discharge unit 112 and storing the mixed cement, and a mixing unit 140 in communication with the storage unit 130 and mixing the mixed cement and water. ; A screw 210 rotatably installed in the storage unit 120 to transfer the mixed cement, and a mixing unit rotatably installed in the mixing unit 140 and interlocked with the screw 210 to mix the mixed cement and water ( A stirring mechanism 200 with 220; A driving device 300 for driving the screw 210; In the intermittent apparatus including a supply device 400 for supplying water to the mixing unit 140 via the transfer line 410 connected to the mixing unit 140, the storage unit 130, toward the lower side The pressure distribution mechanism 500 is provided with a sloped surface 510 which is inclined outwardly and spaced apart from the screw 210 in the upward direction along the longitudinal direction of the screw 210. It is effective to keep it constant.

Description

Silo Apparatus {Silo Apparatus}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a silo apparatus, the structure of which is simple and the mixing apparatus can be made constant to produce high quality mortar.

In general, the siro apparatus is temporarily installed at a construction site to temporarily receive mixed cement commercialized by mixing cement and sand in advance, and generates mortar by stirring water and mixed cement supplied from the outside. Discharge.

1 is a view showing a conventional siro apparatus, referring to the conventional siro apparatus with reference to FIG. 1 as follows.

The conventional siro apparatus includes a sieve 110 having an inlet 111 through which the mixed cement flows, an outlet 112 communicating with the inlet 111 and having a narrower diameter, and a discharge portion of the siro 110. A siro main body 100 having a storage unit 130 in communication with 112 and storing a mixed cement, and a mixing unit 140 in communication with the storage unit 130 and mixing mixed cement and water; A screw 210 rotatably installed in the storage unit 120 to transfer the mixed cement, and a mixing unit rotatably installed in the mixing unit 140 and interlocked with the screw 210 to mix the mixed cement and water ( A stirring mechanism 200 with 220; A drive device 300 for driving the screw 210; A supply device 400 for supplying water to the mixing unit 140 through a transfer line 410 connected to the mixing unit 140; And an opening and closing device 800 installed at the discharge part 112 of the inter path 110 to open and close the discharge part 112.

On the other hand, look at the generation of the mortar using the above-described siro apparatus as follows.

When the mixed cement is introduced into the inter 110 between the apparatus 100, the introduced mixed cement moves to the storage 130.

At this time, when the driving device 300 of the transfer device 200 is operated, while the screw 210 is rotated, the mixed cement is transferred to the mixing unit 140 of the main body 110.

On the other hand, when the mixing cement is located in the mixing unit 140, the mixing unit 140 is supplied with water by the supply device 400, the mixing cement by the mixing unit 300 in conjunction with the screw 210 And water are mixed to form mortar. At this time, the generated mortar is pushed out by the mixed cement which is continuously introduced and discharged to the outside.

However, in the above-described siro apparatus, when the mixed cement flows into the siro 110 and accumulates from the storage 130 to the inlet 111 (A range of FIG. 1), the mixed cement is stored by its own load. The density of the mixed cement in the portion 130 is increased, thereby increasing the stress acting on the screw 210 and overloading the screw 210. In addition, since the inflow portion 111 becomes narrower downward, the stress applied to the screw 210 portion will be very large.

In particular, when the humidity in the storage unit 130 is high, the cohesive force of the mixed cement becomes larger, and accordingly, the load on the screw 210 is also increased.

On the other hand, if the screw 210 is overloaded as described above, the screw 210 is not easy to rotate. Therefore, a large amount of energy is required for the driving device 300 to drive the screw 210, which leads to unnecessary waste of energy, and the driving of the screw 210 is not stable.

In addition, when the screw 210 is overloaded, the number of revolutions of the screw 210 is different from the initially set number of revolutions, and thus, the amount of mixed cement transferred to the mixing unit 140 is different from the initial amount.

Therefore, while the mixing ratio of the mixing cement conveyed to the mixing unit 140 and the water supplied from the supply device 400 is different, poor mortar is generated.

On the other hand, in order to solve the above problems, Republic of Korea Utility Model Publication No. 20-0134555 (mixed cement supply siro device) was devised.

The siro apparatus (Korean Registered Utility Model Publication No. 20-0134555), the inlet portion 111 of the siro main body 100 through the dispersion unit 120 having an inclined surface 121 to reduce the pressure acting on the screw 210 In the bottom portion), the mixed cement introduced into the path 110 is dispersed while colliding with the inclined surface 121 of the dispersing part 120 (see FIG. 1), so as not to be agglomerated.

However, the siro apparatus (Korean Registered Utility Model Publication No. 20-0134555) flows into the discharge unit 112 while the mixed cement dispersed by the dispersion unit 120 has a narrow width, and is stored with the discharge unit 112. Between the parts 130 (b range in Fig. 1) are again packed together. As a result, the concentrated stress acts on the screw 210, and thus, the above-mentioned problem cannot be solved properly.

In addition, in order to solve the above problems, Republic of Korea Patent No. 10-0668066 (Siro device and its operation method) was invented.

The siro apparatus (Korean Patent No. 10-0668066) is provided with a vibration member (reference numeral 130 of the Republic of Korea Patent No. 10-0668066), in order to reduce the stress acting on the screw 210, the adjusting unit (South Korea Registered Patent 10-0668066, reference number 200).

However, the siro apparatus (Korean Patent No. 10-0668066) is provided with a vibration member 130 and the adjusting unit 200, the structure is complicated, manufacturing costs are high, and maintenance is difficult.

In addition, since the vibrating member 130 and the adjusting unit 200 have a large volume, the entire volume of the apparatus is increased, thereby taking up a lot of installation space.

The present invention has been invented to solve the above problems, it is driven stably, it is possible to maintain a constant mixing ratio of the mixing cement and water, as well as to solve the problem to provide a device between the simple structure.

The present invention for solving the above problems, there is provided between the inlet portion and the inlet portion in which the mixed cement flows, the discharge portion is in communication with the inlet portion and narrow, and the storage portion in communication with the discharge portion between the storage portion is stored And a siro body in communication with the storage unit and having a mixing unit where the mixing cement and the water are mixed; A stirring mechanism rotatably installed in the storage unit for transferring the mixed cement, and a mixing unit rotatably installed in the mixing unit and interlocking with the screw to mix the mixing cement and water; A driving device for driving a screw; A through apparatus including a supply device for supplying water to a mixing part via a transfer line connected to the mixing part, wherein the storage part has an inclined surface that is inclined outwardly downwards from the screw along the longitudinal direction of the screw. Characterized in that the pressure distribution mechanism is arranged reinforcement spaced apart at a predetermined interval in the upward direction.

According to the present invention as described above, by lowering the pressure applied to the screw, to facilitate the operation of the screw, it is possible to maintain a constant mixing ratio of the mixing cement and water, the structure of the pressure distribution mechanism is simple, the production cost is low and maintained It is easy to repair.

Hereinafter will be described in detail with reference to the accompanying drawings.

In addition, in describing the present invention, the same reference numerals are used for the same components as those of the conventional interlayer apparatus.

Figure 2 is a partial cross-sectional view showing a siro apparatus according to the present invention, Figure 3 is a cross-sectional view taken along line AA of Figure 2, Figure 4 is a perspective view showing a pressure distribution mechanism according to the present invention, Figure 5 is a cross section according to the present invention Figure 6 is a schematic diagram showing the water supply process of the apparatus, Figure 6 is a schematic diagram showing the electrical connection between the components of the apparatus according to the present invention.

2 and 5, the siro apparatus, the siro body 100, the stirring mechanism 200 is installed on the siro body 100, the siro body 100 is installed on the stirring mechanism 200 A driving device 300 for driving, a supply device 400 for supplying water to the siro body 100, a pressure distribution mechanism 500 installed in the siro body 100, a driving device 300 and a supply device And a control unit 700 for operating the control unit 400 and the opening and closing device 800 'installed in the siro main body 100 and operated and controlled by the control unit 700.

The siro main body 100, the flow path between the mixed cement flows 110, the dispersal portion 120 is installed in the path 110, and the storage unit 130 is in communication with the path 120, the mixed cement is stored And a mixing unit 140 in communication with the storage unit 130 and mixing the mixing cement and water.

The passage 110 has a width narrowing toward the lower side and an inlet portion 111 into which the mixed cement flows, and a discharge portion extending downward from the inlet portion 111 to discharge the mixed cement of the inlet portion 111 ( 112). At this time, since the diameter 110 becomes smaller toward the bottom, the mixed cement supplied to the path 110 stably moves downward. However, due to this structure, as the mixed cement moves downward, the density increases, and the pressure applied to the inside of the passage 110 increases.

The dispersion unit 120 is provided with an inclined surface 121 that is inclined outward toward the lower side, so that the outer surface is spaced apart from the inner surface of the path 110, it is installed in the lower portion of the path 110 through a separate bracket. . At this time, the inclined surface 121 is for preventing the mixed cement from agglomerating, while the mixed cement collides with the inclined surface 121 and is not dispersed and agglomerated.

The storage unit 130 is installed under the discharge part 112 of the path 110 and communicates with the discharge part 112 of the path 110 to store the mixed cement from the discharge part 112 therebetween. .

The mixing unit 140 is located on the side of the storage unit 130 and communicates with the storage unit 130 to receive the mixed cement from the mixing unit 140. At this time, the water supply port 141 for water supply is formed in the upper portion of the mixing unit 140, the discharge port 142 for discharging the mortar generated by mixing the mixing cement and water is formed at the lower end.

2 and 3, the stirring mechanism 200 is rotatably installed in the storage unit 120 and the screw 210 and the mixing unit 140 that are rotatably installed in the storage unit 120 to transfer the cement. The mixing unit 220 is interlocked with the screw 210.

The screw 210 is provided with a screw blade 211 on the outer surface, to linearly move the mixing cement of the storage unit 130 to the mixing unit 140 during rotation.

The mixing unit 220 is connected to the screw 210, and mixes the mixing cement and water during rotation to generate the mortar, and discharges the generated mortar to the outside through the outlet 142 of the mixing unit 140. . On the other hand, the mixing unit 220 is a common one for mixing the mixing cement and water, it is preferable that a plurality of projections (not shown) is formed on the outer surface in order to increase the mixing ratio. In this case, the mixing unit 220 may have a screw shape.

2, the driving device 300 is connected to an end of the screw 210 exposed to the outside to rotate the screw 210. In this embodiment, a conventional power transmission device consisting of a pair of pulleys and a belt is applied to the driving device 300. At this time, the power transmission device is powered by a drive motor (not shown). On the other hand, the driving device 300 may be any one as long as it can drive the screw (210).

Referring to FIG. 5, the supply device 400 includes a pump 440 for pumping water, a transfer line 410 for connecting the mixing unit 140 of the pump 440 and the main body 100, Automatic valve 420 to open and close the transfer line 410, flow meter 430 is installed on the transfer line 410 to be disposed between the mixing unit 140 and the automatic valve 420, and the automatic valve 420 And a pressure gauge 450 installed on the transfer line 410 to be disposed between the pump 440 and a manual valve installed on the transfer line 410 to be disposed between the mixing unit 140 and the flow meter 430. 460).

The pump 440 is operated and controlled by the control unit 700, as long as the pump 440 can pump and supply water to the transfer line 410.

The transfer line 410, a conventional hose or pipe is applied, one end is connected to the pump 440 and the other end is connected to the water supply port 141 of the mixing unit 140, the water from the pump 440 This may be transferred to the mixing unit 140.

The automatic valve 420 is a normal sole valve that is operated and controlled by the control unit 700, is installed on the transfer line 410, and adjusts the amount of water flowing through the transfer line 410.

The flow meter 430 is a conventional measurement of the flow rate of water flowing through the transfer line 410, is installed on the transfer line 410 to be disposed between the automatic valve 420 and the manual valve 460, the control unit Operation control is performed by 700.

The pressure gauge 450 is a conventional one for measuring the hydraulic pressure of the water flowing through the transfer line 410, is installed on the transfer line 410, and is operated and controlled by the control unit 700.

The manual valve 460 is installed on the transfer line 410 to be disposed between the mixing unit 140 of the siro main body 100 and the flow meter 430 of the supply device 400, and manually if necessary It is opened and closed.

2 to 4, the pressure distribution mechanism 500 has a shape in which a flat plate is bent and installed in the storage unit 130 along the longitudinal direction of the screw 210 so as to be positioned above the screw 210. do. At this time, the pressure distribution mechanism 500 forms an inclined surface 510 which is inclined outward as the side thereof goes downward, and both ends thereof are fixed to the storage 130, and the inclined surface 510 is configured to move the mixed cement downward. The inner surface of the storage unit 130 is spaced apart from the predetermined interval.

On the other hand, the inclined surface 510 is dispersed while moving downward along the inclined surface 510, the inclined surface 510 serves to prevent aggregation.

2 and 6, the detection sensor 600 is installed in the storage unit 130 so as to be disposed above the screw 210, and is operated and controlled by the control unit 700 so that the mixed cement is It detects whether or not flow into the storage unit 130, and outputs a detection signal indicating the detection to the control unit 700. On the other hand, as the sensor 600, a proximity switch, etc. may be applied, as long as it is possible to check the presence or absence of inflow of mixed cement.

Referring to FIG. 6, the control unit 700 includes a driving device 300, an automatic valve 420, a flow meter 430, a pressure gauge 450, a pump 440, a detection sensor 600, and an opening and closing device ( 800 ') to control operation.

That is, the control unit 700 controls the driving device 300, the pump 440, and the opening and closing device 800 ′ according to the mixed cement detection signal from the detection sensor 600, and controls the flow meter 430. The automatic valve 420 is operated and controlled according to the flow rate signal from the), and the driving device 300, the pump 440, and the switching device 800 'are operated and controlled according to the pressure signal from the pressure gauge 450.

On the other hand, the control unit 700 is provided with an input unit (I) for inputting a control signal to the control unit 700.

Referring to FIG. 2, the opening and closing device 800 ′ is movably installed in the discharge part 112 of the path 110, and includes a slide gate 810 ′ that opens and closes the inside of the discharge part 112, and a slide gate ( A cylinder 820 'that linearly moves 810'. At this time, the cylinder 820 'is controlled by the control unit 700 in a normal power cylinder.

On the other hand, Figures 7 and 8 is a view showing another embodiment of the siro apparatus according to the present invention, referring to Figures 7 and 8 as follows.

In the present embodiment, the vibrator V, the electric panel C, and the protective mechanism P may be reinforced.

The vibrator (V) is for vibrating the path 110, is installed on the lower outer surface of the inlet 111 of the path 110, the ON-OFF control by the input unit (I). On the other hand, the vibrator (V) is a common to generate a vibration using a motor, a detailed description thereof will be omitted.

The electrical panel (C) is installed in the main body 100, the input unit (I) and the control unit 700 is installed and protected from the outside.

The protection mechanism (P) has a structure in which a plurality of bars are connected in a trapezoidal shape and is detachably or securely installed on the upper portion of the electrical panel (C). At this time, a protective tent (not shown) is detachably or fixedly installed on the upper surface of the protection mechanism P, which is rain, snow, or other dusts such as electric panel C, input unit I, and control. This is to make it possible to stably control when the operator controls the input unit (I) is not drawn into the unit 700.

Looking at the operation of the siro apparatus according to the present invention as follows.

First, in the state where the apparatus is installed at the work site, the apparatus is driven through the input unit I.

When the apparatus is driven, the control unit 700 operates the cylinder 820 'of the opening and closing apparatus 800' so that the slide gate 810 'opens the discharge part 112 of the passage 110. do. At this time, the control unit 700 drives the drive device 300 and the supply device 400.

In the above state, if the mixed cement does not flow into the storage unit 130 even after the reference time elapses, the detection sensor 600 that does not detect the mixed cement did not detect the mixed cement by the control unit 700. Output an undetected signal. Here, the control unit 700 receiving the undetected signal of the detection sensor 600 stops the driving of the driving device 300 and the supply device 400, and opens the cylinder 820 'of the opening and closing device 800'. By controlling, the discharge part 112 is closed.

In this case, when the operator drives the vibrator V through the input unit I, the vibrator V vibrates and a vibration force is applied to the inlet 111 of the path 110, thereby inducing the 111. ) Is shaken and the mixed cement fixed to the inner surface of the inlet 111 is separated from the inlet 111. Thereafter, when the apparatus is re-driven through the input unit I, the driving device 300 and the supply device 400 are driven as described below to generate the mortar.

On the other hand, when the mixed cement is supplied to the inter 110 within the reference time, the detection sensor 600 outputs a detection signal indicating that the mixed cement is detected to the control unit 700, the control unit 700 receives the The drive device 300 and the supply device 400 are continuously driven in a state where the discharge part 112 to the 110 is opened.

When the mixed cement is supplied through the passage 110 as described above, the mixed cement moves downward while being collided with the dispersing unit 120, and the dispersed mixed cement particles pass through the discharge unit 112 to store the storage unit 130. Inflow).

At this time, the internal pressure is reduced by the dispersion unit 120, so that the cement mixture is weakened cohesive force passes through the discharge portion 112 having a narrow width, the internal pressure is increased again, thereby increasing the cohesive force again.

However, the mixed cement passed through the discharge part 112 is dispersed once again by the pressure dispersing mechanism 500 before reaching the storage part 130 in which the screw 210 is installed, thereby weakening the cohesive force.

Therefore, the pressure of the mixing cement acting on the screw 210 is lowered, and thus, the operation of the screw 210 is smoothly performed, so that a predetermined amount of the mixing cement is uniformly stored from the storage unit 130 to the mixing unit 140. Transferred.

Meanwhile, while the driving device 300 is driven, the control unit 700 drives the supply device 400.

Accordingly, the control unit 700 drives the pump 440 to supply water to the mixing unit 140.

 Meanwhile, the mixed cement transferred to the mixing unit 140 is mixed with the water supplied by the pump 440 and the mixing unit 220 to generate mortar, and the generated mortar is stored from the storage unit 130. It is discharged to the outside through the outlet 142 of the mixing unit 140 while being pushed by the pressure of the mixed cement flowing in.

Here, in the operation of the supply device 400, the flow meter 430 measures the flow rate of the water flowing through the transfer line 410, outputs a flow signal according to the measured value to the control unit 700, and receives it One control unit 700 controls the flow rate of water flowing through the transfer line 410 by operating the automatic valve 420 in accordance with the received flow signal.

In addition, the pressure gauge 450 measures the pressure of the water flowing through the transfer line 410, and outputs a pressure signal according to the measured value to the control unit 700, the control unit 700 receives the received According to the pressure signal, the driving device 300, the pump 440, and the opening and closing device 800 'are operated and controlled. That is, when the control unit 700 receives a pressure signal indicating that the pressure in the transfer line 410 falls below the reference value from the pressure gauge 450, the driving unit 300 stops the driving of the pump 440 and opens and closes it. The device 800 is operated to cause the discharge portion 112 of the path 110 to be closed.

On the other hand, the worker who wants to manually close the transfer line 410 as necessary can be such that the water is not supplied to the mixing unit 140 using the manual valve 460.

As described above, the siro apparatus according to the present invention, by preventing the mixing cement is agglomerated in the portion adjacent to the screw 210, smooth operation of the screw 210, constant mixing through smooth screw 210 operation By supplying the cement to the mixing part 140, the mixing ratio of the mixing cement and water can be kept constant at all times, and high quality mortar can be produced.

In addition, the structure of the pressure distribution mechanism 500 used to reduce the stress acting on the screw 210 is simple, the manufacturing cost of the pressure distribution mechanism 500 is lowered, thereby lowering the overall unit cost of the apparatus. In addition, maintenance of the pressure distribution mechanism 500 is easy due to the simple structure of the pressure distribution mechanism 500.

1 is a view showing a conventional siro apparatus,

Figure 2 is a partial cross-sectional view showing a siro apparatus according to the present invention,

Figure 3 is a cross-sectional view taken along line A-A of Figure 2, Figure 4 is a perspective view showing a pressure distribution mechanism according to the present invention,

Figure 5 is a block diagram showing the water supply process of the intermittent device according to the present invention,

Figure 6 is a block diagram showing the electrical connection between the components of the intermittent device according to the present invention.

7 and 8 are views showing another embodiment of the siro apparatus according to the present invention.

-Explanation of terms for main parts of attached drawings-

100; Sirobody 110; Between

120; Dispersion unit 130; Storage

140; Mixing unit 200; Agitator

210; Screw 220; Mixing section

300; Drive unit 400; Feeder

500; Pressure distribution mechanism 600; Sensor

700; Control units 800, 800 '; Switchgear

I; Input unit V; Vibrator

P; Protection

Claims (5)

It is in communication with the discharge portion 112 of the inlet portion 111, the inlet 111 through which the mixed cement is introduced, the inlet portion 111 and the discharge portion 112 narrowing in diameter, and the outlet portion 110 of the interlayer 110. A siro main body 110 having a storage unit 130 in which the mixed cement is stored, and a mixing unit 140 in communication with the storage unit 130 and mixing the mixed cement and water; A screw 210 rotatably installed in the storage unit 120 to transfer the mixed cement, and a mixing unit rotatably installed in the mixing unit 140 and interlocked with the screw 210 to mix the mixed cement and water ( A stirring mechanism 200 with 220; A driving device 300 for driving the screw 210; In the furnace apparatus including a supply unit 400 for supplying water to the mixing unit 140 via the transport line 410 connected to the mixing unit 140, The pressure distribution mechanism 500 having the inclined surface 510 which is inclined outwardly toward the lower portion in the storage unit 130 and spaced apart from the screw 210 in the upward direction by a predetermined distance along the longitudinal direction of the screw 210. )Wow; A detection sensor 600 installed in the storage unit 130 so as to be disposed above the screw 210 to detect the mixed cement flowing into the storage unit 130; Operating apparatus for controlling the detection sensor 600 and the driving device 300, but the control unit 700 is characterized in that the reinforcement is provided with a control unit 700 for controlling the operation of the drive device 300 in accordance with the detection signal from the detection sensor (600) . The method of claim 1, The supply device 400 is an automatic valve 420 for opening and closing the transfer line 410 and a flow meter 430 installed on the transfer line 410 to be disposed between the mixing unit 140 and the automatic valve 420. ), The control unit 700, characterized in that the operation control the automatic valve 420 via the output signal of the flow meter 430 and the output signal from the sensor 600. The method according to claim 1 or 2, The input unit (I) installed in the siro main body 100 to control the operation of the control unit 700, and is installed in the siro 110 and is operated by the input unit (I) to apply the vibration to the siro 110 And a vibrator (V) and a protective mechanism (P) provided on an upper portion of the input unit (I) to protect the input unit (I) from the outside. The method of claim 3, The supply device 400 is a pump 440 operationally controlled by the control unit 700 and the water pressure discharged from the pump 440 to the transfer line 410 by the operation control by the control unit 700 to measure While equipped with a pressure gauge 450 to An intermittent device, characterized in that the control unit (700) operates to control the pump (440) via the output signal from the pressure gauge (450). delete

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