Patent Publication Number: US-11049353-B2

Title: Supplying apparatus of granular material and supplying method of granular material

Description:
BACKGROUND OF THE INVENTION 
     Field of the Invention 
     The present invention relates to a supplying apparatus of granular material and a supplying method of granular material for supplying granular material to a measuring container. 
     Description of the Related Art 
     Conventionally known is a supplying apparatus in which granular material is supplied to a measuring container provided on the lower side in such a manner that granular material becomes a predetermined target measurement value. 
     For example, Patent Literature 1 to be mentioned below discloses a granular material dispenser in which granular material is supplied “n” times in a small amount by shortening each open duration of an on-off valve which opens and closes a flow outlet on the lower end of a granular material container. 
     CITATION LIST 
     Patent Literature 
     PTL 1: Japanese Unexamined Patent Application Publication No. 2011-27728 
     SUMMARY OF THE INVENTION 
     Problems to be Solved by the Invention 
     In the granular material dispenser disclosed in Patent Literature 1, the supplying duration is apt to be elongated when the target measurement value is relatively large. 
     The present invention is proposed in view of the above-mentioned problems and has an object to provide a supplying apparatus of granular material and a supplying method of granular material which improve measurement accuracy when a target measurement value is small in addition to shortening the supplying duration of granular material when the target measurement value is large. 
     Means of Solving the Problems 
     In order to achieve the above-mentioned object, in a supplying apparatus of granular material in which granular material is supplied to a measuring container provided on a lower side so as to reach a target measurement value which is determined in advance, the supplying apparatus includes a storage container storing granular material, a valve body provided in the storage container so as to be opened when granular material is supplied, and a control section controlling open and close operations of the valve body. The control section keeps the valve body at an open position until a detection value of a detecting section of the measuring container becomes a predetermined value smaller than the target measurement value when the target measurement value exceeds a threshold value which is determined in advance; and the control section opens the valve body in a pulsed way until the detection value of the detecting section becomes the target measurement value when the target measurement value is under the threshold value. 
     In order to achieve the above mentioned object, in a supplying method of granular material in which granular material is supplied by opening a valve body provided for a storage container to a measuring container provided on a lower side so as to reach a target measurement value which is determined in advance, the valve body is kept at an open position until a detection value of a detecting section of the measuring container becomes a predetermined value smaller than the target measurement value when the target measurement value exceeds a threshold value which is determined in advance, and the valve body is opened in a pulsed way until the detection value of the detecting section becomes the target measurement value when the target measurement value is under the threshold value. 
     Effects of the Invention 
     The supplying apparatus of granular material and the supplying method of granular material in the embodiment of the present invention as configured above improve measurement accuracy when the target measurement value is small in addition to reducing the supplying duration of granular material when the target measurement value is large. 
    
    
     
       BRIEF DESCRIPTION OF THE DRAWINGS 
         FIG. 1A  and  FIG. 1B  diagrammatically illustrate one example of a supplying apparatus of granular material in accordance with one embodiment of the present invention;  FIG. 1A  is a diagrammatic side view, and  FIG. 1B  is a partially omitted diagrammatic plan view. 
         FIG. 2A  and  FIG. 2B  are partially broken diagrammatic vertical sectional views corresponding to the line X to X in  FIG. 1B . 
         FIG. 3A  to  FIG. 3D  diagrammatically illustrate one example of a valve body of the supplying apparatus,  FIG. 3A  is a diagrammatic perspective view,  FIG. 3B  is a diagrammatic side view, 
         FIG. 3C  is a diagrammatic front view, and  FIG. 3D  is a diagrammatic back view. 
         FIG. 4  illustrates a diagrammatic system of one example of a blending system to which the supplying apparatus is incorporated. 
         FIG. 5A  is a control block diagram of the blending system, and  FIG. 5B  is a diagrammatic time chart illustrating one example of basic operations executed in the blending system. 
         FIG. 6A  and  FIG. 6B  are diagrammatic time charts illustrating other examples of basic operations executed in the blending system. 
     
    
    
     DESCRIPTION OF THE EMBODIMENTS 
     The embodiments of the present invention are explained referring to the attached drawings. Some detailed reference numerals which are allotted to other drawings are omitted in some drawings. 
     In the following embodiments, the directions such as the vertical direction are explained under a standard condition in which that the supplying apparatus of granular material of one embodiment is installed. 
       FIG. 1  to  FIG. 6  are diagrammatic views illustrating one example of the supplying apparatus of granular material of the embodiment and one example of basic operations to be executed using the supplying apparatus. 
     As illustrated in  FIG. 1A , a supplying apparatus of granular material  1  in one embodiment of the present invention has a storage container  10  storing granular material and a supplying portion  20  supplying granular material to a supply destination (a measuring container)  7 , referring to  FIG. 4 . In this embodiment, the supplying apparatus  1  is configured so as to supply granular material to the measuring container  7 , i.e., the supply destination, which is provided on the lower side so as to become a predetermined target measurement value. The supplying apparatus  1  and a measuring device including the measuring container  7  can constitute a material measuring apparatus. Specific structure of the supplying apparatus  1  is explained later. 
     The above-mentioned granular material refers to powdered or granular material and includes material in the form of minute flakes, short fibers, slivers, and so on. 
     The material includes any material such as synthetic resin material like resin pellets and resin fibers, metal material, semiconductor material, woody material, material for medicine, and food material. 
     Granular material, for example for molding synthetic resin products, includes natural material (virgin material), pulverized material, master batch material, additive agent, and so on. Granular material can include reinforced fibers such as glass fibers and carbon fibers. 
     In the embodiment, the supplying apparatus  1  is incorporated into a material blending apparatus which is provided for a blending system A blending several kinds of granular material so as to have a predetermined blend ratio, i.e., mass ratio, as illustrated in  FIG. 4 . 
     The blending system A has a plurality of supplying apparatus  1  ( 1 A,  1 B,  1 C,  1 D) which store different kinds of granular material respectively, and the measuring container  7  receiving and measuring each kind of granular material supplied from the supplying apparatus  1 . The drawings illustrate an example with four supplying apparatus  1 . Four supplying apparatus  1  can include a first supplying apparatus  1 A supplying main natural material, a second supplying apparatus  1 B supplying master batch material, a third supplying apparatus  1 C supplying an additive agent, and a fourth supplying apparatus  1 D supplying pulverized material. When it is not required to distinguish the first supplying apparatus  1 A, the second supplying apparatus  1 B, the third supplying apparatus  1 C, and the fourth supplying apparatus  1 D, the supplying apparatus  1  is used in the following explanation. 
     The blending system A has a mixing tank including a rotatable agitating blade  9  mixing the granular material which is measured in and is discharged from the measuring container  7 . The drawings illustrate an example in which the measuring container  7  and the agitating blade  9  are provided in a unitized casing  6 . The casing  6  has on the top end portion a suitable holding portion holding the storage container  10  of each supplying apparatus  1 . 
     The measuring container  7  is held by the casing  6  via a detecting section  8  consisting of a mass detector such as a load cell. The measuring container  7  has on the upper end side an inlet opening upward. The inlet of the measuring container  7  is provided so as to receive the granular material supplied from each supplying apparatus  1  on an upstream side, i.e., or an upper side. The measuring container  7  has on the lower end side an outlet opening downward and an open-close mechanism opening and closing the outlet. In the drawings, a cover body is provided as the open-close mechanism which is moved upward in an oblique direction like a pendulum and opens the outlet. The open-close mechanism is not limited to such an example and can be a slide shatter which slides in the approximately horizontal direction, a flap-like valve body supported by an arm-like support portion which rotates around a rotary axis on the side of the measuring container  7 , or other configurations. 
     The agitating blade  9  is positioned on the lower side in the measuring container  7  and is rotated by a suitable driving section. The granular material mixed in the mixing tank having the agitating blade  9  is supplied to a molding machine  2 , which is the supply destination of the blending system A. In the example in the drawings, the casing  6  is provided on the molding machine  2 . The molding machine  2  can be, for example, an injection molding machine for molding synthetic resin products, an injection molding machines for other materials, other molding machines such as an extrusion molding machine or a compression molding machine for other materials. The supply destination of the blending system A is not limited to a single and can be plural destinations. The granular material mixed in the mixing tank is not limited to be supplied by its own weight to the molding machine  2 , which is the supply destination, and can be pneumatically transported to the supply destination from the mixing tank or the storage portion on the downstream side, i.e., lower side, of the mixing tank. In this case, in place of providing the casing  6  on the molding machine  2 , the casing  6  can be supported by a suitable frame or pedestal. 
     The drawings illustrate an example in which the blending system A has a pneumatic transporter  4  pneumatically transporting granular material supplied from a material supply source  3  to each supplying apparatus  1 . The drawings also illustrate a first material supply source  3 A connected to the first supplying apparatus  1 A via a material transport pipe, a second material supply source  3 B connected to the second supplying apparatus  1 B via a material transport pipe, a third material supply source  3 C connected to the third supplying apparatus  1 C via a material transport pipe, and a fourth material supply source  3 D connected to the fourth supplying apparatus  1 D via a material transport pipe. When it is not required to distinguish the first material supply source  3 A, the second material supply source  3 B, the third material supply source  3 C, and the fourth material supply source  3 D, the material supply source  3  is used in the following explanation. 
     In the drawings, the first material supply source  3 A, the second material supply source  3 B, and the third material supply source  3 C are illustrated in the formed of a tank. The fourth material source  3 D is illustrated as a pulverizer for by-products of molding such as sprue, runner and burr which are separated from a product after taking out of the molding machine  2 , or material to be pulverized such as inferior molded products. The material to be pulverized can be put into a charge hopper of the pulverizer by a transport means such as a suitable extraction apparatus of by-products or a belt conveyor. 
     The material transport pipe connected to the material supply source  3  is connected to a hopper-like collecting portion  19  provided on the upper end portion of the storage container  10  of each supplying apparatus  1 . An air suction pipe connected to the pneumatic transporter  4  is connected to the collecting portion  19 . The collecting portion  19  has a separation portion separating granular material from transport air directed to the air suction pipe. Any separation portion can be used as far as it separates granular material from transport air, and can include a porous plate body in the form of a perforated metal or a net (mesh) which passes powdered dust in addition to transport air and does not pass granular material, which is raw material, or a can include baffle board in the shape of an umbrella. Other separation portions with various structures can be also used. A separation mechanism of the collecting portion  19  can be a cyclone type structure separating granular material from transport air. 
     The air suction pipe connected to the collecting portion  19  is connected to the pneumatic transporter  4  via a transport air changeover valve  5 . The transport air changeover valve  5  is configured to be switched so as to communicate one of a plurality of air suction pipes with a suction side of the pneumatic transporter  4 . The pneumatic transporter  4  has a suitable dust collecting portion such as a bag filter or a cyclone filter, and a suction blower constituting a transport air source. 
     The blending system A has a control unit  30  having a control section  31  constituted with a CPU and so on which control members of the blending system A, referring to  FIG. 5A . The control unit  30  can be additionally provided for suitable portions of the blending system A, for example, the casing  6  or the pneumatic transporter  4 , or can be located separately. 
     The control unit  30  has a display-operation section  32  constituting a display portion and an operation portion for various settings, inputting and displaying. The control unit  30  also has a memory section  33  storing set conditions and input values set and input by the display-operation section  32 , programs such as control programs for executing each mode to be mentioned later, previously set operation conditions, the memory section  33  being constituted with several kinds of memories. The display-operation section  32 , the memory section  33 , the above-mentioned detecting section  8 , and the supplying portion  20  (valve body driving section  27 ) of each supplying apparatus  1  are connected to the control section  31  respectively via a signal line or the like. The transport air source of the pneumatic transporter  4 , the transport air changeover valve  5 , the driving portion of the pulverizer constituting the fourth material supply source  3 D, a material sensor provided for each supplying apparatus  1 , the open-close mechanism of the measuring container  7 , the driving portion of the agitating blade  9 , and a material sensor provided for the mixing tank are also connected to the control section  31  respectively via a signal line or the like. The control section  31  can be connected to the material sensor and the outlet of the material supply source  3  if necessary. 
     The blending system A as configured above executes a transport mode for pneumatically transporting granular material to the supplying apparatus  1  from the material supply source  3 , a measuring mode in the measuring container  7 , and a mixing mode in the mixing tank. In the transport mode, when the material sensor of the supplying apparatus  1  outputs a material request signal, the transport air changeover valve  5  is switched so as to communicate the air suction pipe connected to the collecting portion  19  of the supplying apparatus  1  with the pneumatic transporter  4 , and the transport air source of the pneumatic transporter  4  is driven. Thus, granular material is transported to the supplying apparatus  1  from the material supply source  3 . In case that material request signals are output from the material sensors of a plurality (all) of the supplying apparatus  1  at the initial driving state of the blending system A, the transport mode toward each supplying apparatus  1  can be sequentially executed in accordance with a previously set priority order. 
     When the transport mode is executed as mentioned above and granular material is stored in each supplying apparatus  1 , the measuring mode is executed. 
     In the measuring mode, each supplying portion  20  of the supplying apparatus  1  can be controlled in such a manner that each kind of granular material becomes a previously set target measurement value, and that one batch measuring can be executed by sequentially supplying each kind of granular material to the measuring container  7 . The target measurement value of each kind of granular material can be calculated and set based on a target value of one batch and the mass ratio of each kind of granular material. Specific control embodiment of each supplying portion  20  of the supplying apparatus  1  is to be mentioned later. 
     When one batch measurement amount of granular material is stored in the measuring container  7  and the material sensor of the mixing tank outputs a material request signal, the outlet of the measuring container  7  can be opened to discharge granular material to the mixing tank, the agitating blade  9  can be rotated, and the mixing mode can be executed. When the measuring container  7  becomes empty, the measuring mode can be executed and one batch measurement amount of granular material can be stored in the measuring container  7  until a material request signal is output from the material sensor of the mixing tank. 
     After granular material is mixed in the mixing tank as mentioned above, a molding preparation procedure such as a trial operation or a test operation is duly executed in the molding machine  2  and is transferred to a stable operation procedure in which a molding procedure is successively executed. Material to be pulverized which is produced in the molding machine  2  is duly pulverized by the pulverizer constituting the fourth material supply source  3 D. When a material request signal is output from the material sensor of the mixing tank in a similar manner, the outlet of the measuring container  7  is opened and the mixing mode is executed; when the measuring container  7  becomes empty, the measuring mode is executed. When a material request signal is output from each material sensor of the supplying apparatus  1 , the transport mode is executed. Each mode to be executed in the blending system A is not limited to the modes mentioned above, and several variations are possible. 
     The embodiment in which granular material is pneumatically transported to the collecting portion  19  from the material supply source  3  is not limited to the above-mentioned suction transport; compressed air can be supplied to the outlet of the material supply source  3  and granular material can be transported under pressure to the collecting portion  19 . In such a case, a discharge pipe having a suitable dust collecting portion can be connected to the collecting portion  19 . The embodiment of supplying (feeding) granular material to each supplying apparatus  1  is not limited to pneumatic transport; granular material can be supplied (fed) by dropping due to the gravity from the upstream side (upper side); or granular material can be supplied by an operator. 
     In place of the embodiment in which each of the plurality of supplying apparatus  1  has the supplying portion  20  to be mentioned later, the supplying portion can be provided for at least one of the supplying apparatus and other supplying apparatus can have other supplying portions. Such a supplying portion includes a slide shutter, a screw feeder, a vibration feeder, a mass feeder, a rotary feeder, and a table feeder; and other structures can be used. 
     In the above-mentioned example, the mixing tank is provided for the casing  6 ; however, other mixing mechanisms can be provided in place of such an example. For example, granular material measured and blended in the measuring container  7  can be pneumatically transported and mixed in the collecting portion. Specific structure of each member and each portion which are incorporated into the blending system A is not limited to those mentioned above and various modifications are possible. 
     In place of the embodiment in which the material blending apparatus, i.e., blending system A, is configure by incorporating a plurality of supplying apparatus  1 , the material measuring apparatus, i.e., measuring system, including a single supplying apparatus  1  can be adopted. In such a case, the mixing tank and the mixing mechanism are not required to be provided. 
     In the supplying apparatus  1 , the storage container  10  has a valve body  21  which is opened when granular material is supplied as illustrated in  FIG. 1A  and  FIG. 2 . The valve body  21  is controlled by the control section  31  so as to be opened or closed and constitutes the supplying portion  20  supplying granular material to the supply destination, i.e., the measuring container  7 . In this embodiment, the valve body  21  is in the shape of a column which is slid along the opening direction of a guide hole  17  provided for the storage container  10 . The supplying portion  20  including the valve body  21  is detailed later. 
     The storage container  10  is formed like a hopper in such a manner that the upper region is tubular and the lower region is gradually tapered downward. In this embodiment the upper region of the storage container  10  is approximately in the shape of a square tube of which plan view is rectangular as illustrated in  FIG. 1B . In the example in the drawings, the upper region of the storage container  10  is approximately in the shape of a square on the plan views. 
     As illustrated in the embodiment in  FIG. 1 , among circumferential wall portions defining four sides of the storage container  10 , a first side wall portion  11  and a second side wall portion  12 , which are adjacent each other, are in the shape of perpendicular plates roughly along the entire up and down direction. The example in the drawing illustrates that the upper end side region of the first side wall portion  11  is a slant plate slanting downward in the outward direction. In the drawing, among the circumferential wall portions defining four sides of the storage container  10 , a third side wall portion  13  and a fourth side wall portion  14 , which are adjacent each other, are slant plates which slant downward to a corner of the first side wall portion  11  and the second side wall portion  12  from a lower edge of the upper region being the approximately perpendicular plate. 
     A portion to be held  12   a  which is held by a holding portion of the casing  6  is provided for the second side wall portion  12 , which is one of the four circumferential wall portions. In the drawings, the portion to be held  12   a  is configured to define a hole-like recess which penetrates in the vertical direction and into which a piece constituting the holding portion is inserted, the piece being shaped corresponding to the shape of the second side wall portion  12 . 
     A cover body  18  is provided on the upper end side of the storage container  10  so as to open and close the opening on the upper end side. One side portion of the cover body  18  is rotatably coupled to a rotary coupling member such as a hinge at the upper end portion of the first side wall portion  11 , and is rotated relative to the storage container  10  to be opened or closed. In the drawing, a fastening metal fitting is provided on the upper end portions of the third side wall portion  13  and the fourth side wall portion  14  for fastening the other side portion of the cover body  18 . The cover body  18  is not limited to the above-mentioned example which is rotatably coupled to the storage container  10  and can be detachably provided. The above-mentioned collecting portion  19  can be provided for the cover body  18 . In such a case, the cover body  18  can be provided with an opening which is communicated with the outlet of the collecting portion  19  or into which the discharge pipe is inserted. The reference numeral  14   a  in  FIG. 1A  indicates a window portion which is provided for the fourth side wall portion  14  and through which the inside is visible. 
     A bottom wall portion  15  is provided on the lower end side of the storage container  10 . The guide hole  17  is provided so as to penetrate the bottom wall portion  15  in the vertical direction. In this embodiment, the guide hole  17  is configured in such a manner that the dimension along the opening direction (vertical direction) of the guide hole  17  is larger than the thickness of the bottom wall portion  15  of the storage container  10  for which the guide hole  17  is provided, and the guide hole  17  constitutes a hole of a resin tubular member (tubular member) attached to the storage container  10 . In such a configuration, compared with the example in which the guide hole  17  is constituted by penetrating the wall portion (bottom wall portion)  15  itself constituting the storage container  10 , the valve body  21  to be mentioned later is stably slid. The tubular member  16  is made of resin, thereby eliminating operation failures caused by biting by granular material between the circumferential edge portion of the guide hole  17  and the open circumferential edge portion of an opening, i.e., an outlet  24  to be mentioned later in this embodiment, provided for the valve body  21 . 
     The tubular member  16  can be a molded product made from resin material with good abrasion resistance and slidability such as polyacetal (POM), and oil implemented polyacetal, or can be a so-called bushing. The thickness dimension, in the vertical direction, of the tubular material  16  can be duly determined in view of the stable sliding of the valve body  21 , and downsizing the dimension in the vertical direction of the valve body  21  to be mentioned later. In the example in the drawings, the tubular member  16  is projected toward the lower side further than the lower face of the bottom wall portion  15 . Also in the example, the tubular member  16  is attached to a mounting hole of the bottom wall portion  15  in such a manner that a flange portion provided on the outer circumferential edge portion on the upper end side of the tubular member  16  is engaged to the circumferential edge portion, on the inner side of the storage container  10 , of the mounting hole of the bottom wall portion  15 . 
     The shape of the guide hole  17  of the tubular member  16  when seen in the opening direction depends on the shape of the valve body  21 , to be mentioned later, when seen in the axial direction. In the embodiment, the guide hole  17  is circular when seen in the opening direction. Also in the embodiment, the guide hole  17  is gradually enlarged in diameter toward the lower side, which is the outside of the storage container  10 . The guide hole can be a hole provided for the bottom wall portion  15  of the storage container  10  in place of the embodiment in which the guide hole  17  is the hole of the tubular member  16  made from resin. 
     The supplying portion  20  has a valve body driving section  27  which moves the valve body  21  to a closed position or an open position, as illustrated in  FIG. 1A  and  FIG. 2 . In the embodiment, the valve body driving section  27  is a cylinder having a rod  28  which is elongated or contracted in the vertical direction relative to a cylinder body. The cylinder constituting the valve body drive body  27  includes an air cylinder, a hydraulic cylinder, and an electric cylinder. In the embodiment, the valve body drive body  27  is provided in the storage container  10 . In addition, a bracket-like holding portion  29  holding the valve body driving section  27  is fixed to the inner wall of the storage container  10 . An air supplying pipe connected to the valve body driving section  27  can be provided so as to penetrate the circumferential wall portion of the storage container  10 . In this case, the connection portion of the air supplying pipe can be provided for the outer wall portion of the circumferential wall of the storage container  10 . 
     The valve body  21  is columnar in such a manner that the axial direction is along the vertical direction. The valve body  21  has a closing portion  25  provided in the guide hole  17  when the valve body  21  is at the closed position, and a material supplying passage  22  communicating the inside of the storage container  10  and the outside of the storage container  10  when the valve body  21  is at the open position. In such a configuration, granular material is more efficiently inhibited from being bitten, compared with a flap-like valve body closing the outlet of the storage container  10  or a conic valve body closing the valve body and the outlet by being fitted thereinto. Thus, the valve body  21  is opened and closed at relatively high speed, so that the supply amount at one opening operation is effectively reduced, like the supplying mode to be mentioned later. 
     As illustrated in  FIG. 2B , the closing portion  25  is provided in the guide hole  17  when the valve body  21  is at the closed position; and the guide hole  17  is closed. Therefore, the structure is further simplified compared with an example in which a container tube housing the valve body  21  is provided in the storage container  10  so as not to open an inlet  23  of the valve body  21  in the storage container  10  when the valve body  21  is at the closed position. 
     In the embodiment, the material supplying passage  22  of the valve body  21  is provided so as to penetrate the valve body  21  in such a manner that the inlet  23  and the outlet  24  open on the side circumferential face  21   a  of the valve body  21 . As illustrated in  FIG. 2A , the material supplying passage  22  is obliquely configured such that the inlet  23  opens in the storage container  10  and the outlet  24  opens outside the storage container  10  at the supply position (open position) where the valve body  21  supplies granular material. In such a configuration, the outlet  24  obliquely opens relative to the axial direction of the valve body  21  and granular material in the storage container  10  is discharged to one side of the radial direction of the valve body  21 . As mentioned above, when granular material is designed to be discharged to the inlet of the measuring container  7  on the lower side from each storage containers  10  of the plurality of supplying apparatus  1 , the valve body  21  of each storage container  10  is arranged so as to discharge granular material toward the central side of the measuring container  7 , so that granular material is inhibited from scattering outside the measuring container  7 . 
     In the embodiment, the valve body  21  is approximately cylindrical as illustrated in  FIG. 3A  to  FIG. 3D . In such a configuration, compared with the example in which the valve body  21  is in the shape of a rectangular column, and the inlet  23  and the outlet  24  are provided so as to open on the side face, the open area, i.e., square measure along the circumferential direction, of the inlet  23  and the outlet  24  which open on the side circumferential face  21   a  is effectively enlarged. In addition, the valve body  21  is approximately the same in diameter roughly along the entire axial direction. 
     In the embodiment, the closing portion  25  of the valve body  21  is provided for the outer side of the storage container  10  further than the material supplying passage  22  in the axial direction of the valve body  21  in such a manner that the material supplying passage  22  is positioned in the storage container  10  when the valve body  21  is at the closed position. In such a configuration, granular material flows through the inlet  23  to the material supplying passage  22  in the storage container  10  when the valve body  21  is at the closed position, so that granular material is promptly discharged when the valve body  21  is at the open position. The closing portion  25  is provided in such a manner that the approximately entire outer circumferential face of the closing portion  25  abuts on or becomes adjacent to the inner circumferential face of the guide hole  17  when the valve body  21  is at the closed position. 
     In the embodiment, the rod  28  of the valve body driving section  27  is coupled to an upper end portion  26  of the valve body  21 ; and the closing portion  25  is constituted by the lower end portion of the valve body  21 , i.e., an outer end portion of the storage container  10  in the axial direction of the valve body  21 . As illustrated in  FIG. 2B , the closed position of the valve body  21  is such that the rod  28  of the valve body driving section  27  in the storage container  10  is contracted; and as illustrated in  FIG. 2A , the open position of the valve body  21  is such that the rod  28  is elongated. The valve body  21  can be configured such that a lower end face  21   b  of the valve body  21  is on the roughly same plane as the lower end face of the tubular member  16  constituting the guide hole  17  when the valve body  21  is at the closed position. In the drawings, the lower end face  21   b  of the valve body  21  is positioned slightly under the lower end face of the tubular member  16  when the valve body  21  is at the closed position; however, the lower end face  21   b  of the valve body  21  and the lower end face of the tubular member  16  can be on the same plane, or the lower end face  21   b  of the valve body  21  can be slightly on the upper side of the lower end face of the tubular member  16 . Namely, the valve body  21  can be configured in such a manner that the closing portion  25  of the valve body  21  does not project into the lower side of the circumferential edge portion of the lower end side (outer side) of the guide hole  17 , i.e., the lower end face of the tubular member  16 , at the closed position. In the drawings, a C-chamfered plane is provided on the outer circumferential edge portion of the lower end face  21   b . The upper end portion  26  of the valve body  21  is provided with a female screw hole to be coupled with the rod  28  so as to open on the upper end face  21   c  as illustrated in  FIG. 3A . The outer circumferential edge portion of the upper end face  21   c  can be provided with a suitable chamfered portion. 
     The material supplying passage  22  slants relative to the axial direction of the valve body  21 , i.e., the elongating or contracting direction of the rod  28 , in the vertical direction. The slant angle of the material supplying passage  22  can be duly determined in view of downsizing the dimension of the valve body  21  in the axial direction and improving discharge ability of granular material; the slant angle can be, for example, about 20 to 60 degrees relative to the face perpendicular to the axial direction of the valve body  21  (the horizontal face); the slant angle is about 35 degrees in the drawings. The material supplying passage  22  is provided in an approximately linear fashion without curving or without bending in the middle thereof. In the embodiment, the material supplying passage  22  is provided in such a manner that the axial center of the material supplying passage  22  and the axial center of the valve body  21  are on the approximately same plane. In addition, the valve body  21  is positioned in such a manner that the slant direction of the material supplying passage  22  comes to be along the slant direction of the fourth side wall portion  14 , i.e., one of the circumferential wall portions of the storage container  10 , which slants as mentioned above. Namely, the valve body  21  is positioned in such a manner that the outlet  24  opens toward the second side wall portion  12  which is an approximately perpendicular plate of the storage container  10 . In such a configuration, granular material flowing along the fourth side wall portion  14  smoothly flows along the material supplying passage  22  when the valve body  21  is at the open position. 
     The opening, directing obliquely upward, of the material supplying passage  22  constitutes the inlet  23  and the opening, directing obliquely downward, constitutes the outlet  24 . 
     The inlet  23  is provided so as to open on the side circumferential face  21   a  on the upper end side of the valve body  21 . The inlet  23  is approximately in the shape of a circle (an exact circle) seen in the penetrating direction of the material supplying passage  22 . As illustrated in  FIG. 2A  and  FIG. 2B , the inlet  23  is positioned in the storage container  10  in both cases when the valve body  21  is at the open position and at the closed position; and the lower edge of the open circumferential edge portion is positioned at roughly the same height as the circumferential edge portion  17   a  (inner circumferential edge portion), on the inner side of in the storage container  10 , of the guide hole  17  when the valve body  21  is at the open position. 
     The diameter (inner diameter) of the inlet  23  can be duly determined in view of strength of the valve body  21  and of improving discharge ability of granular material; it can be around three-fifths to nine-tenths of the diameter (outer diameter) of the valve body  21 ; it is about four-fifths in the example in the drawings. 
     In the embodiment, the open circumferential edge portion of the inlet  23  has a chamfered portion  23   a . In such a configuration, granular material hardly gets lodged at the open circumferential edge portion of the inlet  23 , so that granular material smoothly flows into the material supplying passage  22 . The chamfered portion  23   a  is provided entirely along the open circumferential edge portion of the inlet  23 . In the drawings, the chamfered portion  23   a  is a C-chamfered plane, but it can be an R-chamfered plane. In place of providing the chamfered portion  23   a  for the entire open circumferential edge portion of the inlet  23 , the chamfered portion  23   a  can be provided only for the region of the open circumferential portion of the inlet  23  on the side of the closing portion  25 ; in addition, the chamfered portion  23   a  is not required to be provided. 
     The outlet  24  is provided so as to open on the side circumferential face  21   a , which is on the lower end side of the valve body  21  and is opposite to the inlet  23  in the radial direction. The outlet  24  is provided in such a manner that the lower end edge of the open circumferential edge portion is positioned on the upper side of the lower end face of the tubular member  16  when the valve body  21  is at the closed position, as illustrated in  FIG. 2B . In the embodiment, the outlet  24  opens also in the storage container  10  in such a manner that a space is formed between the open circumferential edge portion (the upper end edge), of the outlet  24  on the inner side of the storage container  10  and the inner circumferential edge portion  17   a  of the guide hole  17  when the valve body  21  is at the open position as illustrated in  FIG. 2A . Such a configuration reduces operation failures caused by biting by granular material between the inner circumferential edge portion  17   a  of the guide hole  17  and the open circumferential edge portion of the outlet  24  on the inner side of the storage container  10 . The open area of the outlet  24  which opens in the storage container  10  when the valve body  21  is at the open position can be duly determined so as to pass granular material. In such a configuration, the outlet  24  which opens in the storage container  10  can be functioned as the inlet. 
     In the embodiment, the diameter (the inner diameter) of the outlet  24  is larger than the diameter (the inner diameter) of the inlet  23  as illustrated in  FIG. 3C  and  FIG. 3D . Namely, the material supplying passage  22  is gradually enlarged in diameter toward the outlet  24 . When the outlet  24  opens in the storage container  10  at the open position as mentioned above, the open area of the outlet  24  opening outside the storage container  10  at the open position is apt to be reduced; however, in the above-mentioned configuration, the open area of the outlet  24  opening outside the storage container  10  at the open position is increased. When the valve body  21  is at the open position, the open area of the outlet  24  opening outside the storage container  10  can be duly determined in view of downsizing the valve body  21  and improving the discharge ability of granular material, or can be roughly the same as the open area of the inlet  23 . 
     In the embodiment, as illustrated in  FIG. 2 , the inner diameter of an upper supplying passage  22   a , on the side of the inlet  23 , of the material supplying passage  22  is the same as that of the inlet  23 ; and the inner diameter of a lower supplying passage  22   b , on the side of the outlet  24 , of the material supplying passage  22  is gradually enlarged in diameter toward the outlet  24 . Namely, the material supplying passage  22  is gradually enlarged in diameter from the middle region toward the outlet  24 . In place of such a configuration, the entire material supplying passage  22  can be gradually enlarged in diameter toward the outlet  24 . 
     In the embodiment, the outlet  24  is approximately in the shape of an ellipse which is elongated in the roughly axial direction of the valve body  21  when seen in the penetrating direction of the material supplying passage  22 . Namely, the lower supplying passage  22   b  is gradually enlarged in diameter in the roughly axial direction toward the outlet  24 . In other words, the diameters of the inlet  23  and the outlet  24  along the circumferential direction of the valve body  21  are approximately the same. 
     In the embodiment, a chamfered portion  24   a  is provided at the open circumferential edge portion of the outlet  24  at least on the side of the closing portion  25 . Such a configuration reduces operation failures caused by biting by granular material between the open circumferential edge portion of the outlet  24  on the side of the closing portion  25  and the guide hole  17 . In the embodiment, the chamfered portion  24   a  is provided entirely along the open circumferential edge portion of the outlet  24 . In place of providing the chamfered portion  24   a  for the entire open circumferential edge portion of the outlet  24 , the chamfered portion  24   a  can be provided only for the region of the open circumferential portion of the outlet  24  on the side of the closing portion  25 ; or the chamfered portion  24   a  is not required to be provided. 
     The valve body  21  and the storage container  10  can be made from suitable metal material. 
     A grating member for preventing insertion of fingers can be provided on the upper side of the valve body driving section  27  in the storage container  10 . 
     Next explained is a method of supplying granular material in one embodiment as one example of supplying mode which is executed using the supplying apparatus  1  of the embodiment, referring to  FIG. 5B ,  FIG. 6A , and  FIG. 6B . In the graphs in  FIG. 5B ,  FIG. 6A , and  FIG. 6B , the horizontal axes indicate time axes, the vertical axes indicate detection values of the above-mentioned detecting section  8  of the measuring container  7 , and the transitions are diagrammatically illustrated. In  FIG. 5B ,  FIG. 6A , and  FIG. 6B , open and close operations of the valve body  21  are diagrammatically illustrated. 
     In the supply method, granular material is supplied by opening the valve body  21  provided for the storage container  10  to the measuring container  7  provided on the lower side in such a manner that granular material becomes a predetermined target measurement value. In the supply method, when the target measurement value exceeds a predetermined threshold value, the valve body  21  is kept at the open position until the detection value of the detecting section  8  in the measuring container  7  becomes a predetermined value smaller than the target measurement value; when the target measurement value is under the above-mentioned threshold value, the valve body  21  is opened in a pulsed way in such a manner that the detection value of the detecting section  8  becomes the target measurement value. The supply method is executed under the control of the above-mentioned control section  31 . Namely, when the target measurement value exceeds the above-mentioned threshold value, the control section  31  keeps the valve body  21  at the open position until the detection value of the detecting section  8  of the measuring container  7  becomes a predetermined value smaller than the target measurement value; when the target measurement value is under the above-mentioned threshold value, the control section  31  opens the valve body  21  in a pulsed way in such a manner that the detection value of the detecting section  8  becomes the target measurement value. 
     In the above-mentioned configuration, when the target measurement value is relatively large, the valve body  21  is kept at the open position until the detection value of the detecting section  8  becomes a predetermined value; compared with the example in which open and close operations of the valve body  21  are repeated, the supplying duration, i.e., the measuring duration, is reduced. When the target measurement value is relatively small, the valve body  21  is opened in a pulsed way in such a manner that the detection value of the detecting section  8  becomes the target measurement value, so that the supply amount per an open operation is remarkably reduced and the measuring accuracy is improved. 
     When plural kinds of granular material are blended in the measuring container  7 , the target measurement value can be calculated and set based on the mass ratio and one-batch target amount input by the display-operation section  32  or input by the display-operation section  32 . The above-mentioned threshold value can be a suitable value in view of improving the measuring accuracy or in view of reducing the measuring duration, or can be varied depending on the kinds of granular material. The threshold value can be a value when the number of opening of the valve body  21  opened in a pulsed way to be mentioned later is equal to or less than 50; the number is preferably equal to or less than 20. The threshold value can be almost the same as a drop value to be mentioned later. 
     As illustrated in  FIG. 5B , when the target measurement value is under the above-mentioned threshold value, the control section  31  opens the valve body  21  in a pulsed way; namely a small amount supplying mode in which the valve body  21  quickly repeats open and close operations is executed. One-time open duration, i.e., the pulse width, of the valve body  21  in the small amount supplying mode can be relatively short in view of improving the measuring accuracy; for example, it can be equal to or less than one second, preferably equal to or less than 0.5 seconds, or more preferably equal to or less than 0.2 seconds. One-time open duration of the valve body  21  in the small amount supplying mode can be set in such a manner that the supply amount in one-time open duration is equal to or less than 1 gram. The closed duration between the pulses of the valve body  21  in the small amount supplying mode can be almost the same as that in the one-time open duration; however, it is larger than the one-time open duration in the drawings. When open and close operations are quickly repeated and the small amount supplying mode is executed, the detection value of the detecting section  8  stepwisely increases; when it becomes the target measurement value, the vale body  21  is closed, and the small amount supplying mode is finished. 
     As illustrated in  FIG. 6A , when the target measurement value exceeds the above-mentioned threshold value, the control section  31  executes a large amount supplying mode in which the valve body  21  is kept at the open position until the measurement value becomes a predetermined value. In  FIG. 6A  and  FIG. 6B , the threshold value is illustrated to be lower than that in  FIG. 5B ; however, they are actually the same. In  FIG. 6A , the above-mentioned predetermined value is set as a previously set drop value, i.e., mass of granular material dropping after the valve body  21  is closed. In the example, in case that the target measurement value exceeds the above-mentioned threshold value, the control section  31  closes the valve body  21  when the detection value of the detecting section  8  becomes a value obtained by subtracting the previously set drop value from the target measurement value. Namely, in the large amount supplying mode in the embodiment, the control section  31  keeps the valve body  21  at the open position until the detection value of the detecting section  8  becomes a value obtained by subtracting the drop value from the target measurement value. In such a configuration, in addition to reducing the measuring duration, granular material is properly supplied considering the drop value after the valve body  21  is closed, and the measuring accuracy is improved. 
     The above-mentioned drop value can be stored in the memory section  33  in advance as an initial data, can be selected from several values depending on the particle diameter or the bulk density of granular material, or can be input and set and input by the display-operation section  32 . The drop value can be corrected based on the actual measurement data as needed and the data in the memory section  33  can be updated each time the large mount supplying mode is executed. In such a case, the drop value can be corrected or updated based on the average movement value of one batch measurement in the previous times. 
     In place of the above, a large amount supplying mode in a modified embodiment illustrated in  FIG. 6B  can be executed. In the modification, in case that the target measurement value exceeds the above-mentioned threshold value, when the detection value of the detecting section  8  becomes a predetermined value (switch value), the control section  31  opens the valve body  21  in a pulsed way in such a manner that the detection value of the detecting section  8  becomes the target measurement value. Namely, in the large amount supplying mode in the modification, the control section  31  keeps the valve body  21  at the open position until the detection value of the detecting section  8  becomes the switch value; when the detection value becomes the switch value, the control section  31  opens the valve body  21  in a pulsed way. In such a configuration, in addition to reducing the measuring duration, after the detection value becomes the switch value, the valve body  21  is opened in a pulsed way, and the supply amount per an open operation is reduced and the measuring accuracy is improved. 
     The above-mentioned switch value can be stored in the memory section  33  in advance as an initial data or can be selected from plural values depending on the particle diameter or the bulk density of granular material. The switch value can be approximately the same as the drop value. 
     The embodiment in which the valve body  21  is opened in a pulsed way after the detection value becomes the switch value can be the same as that in the above-mentioned small amount supplying mode. 
     The large amount supplying mode in the modification, i.e., the second large amount supplying mode, and the large amount supplying mode explained referring to  FIG. 6A , i.e., the first large amount supplying mode, can be selectively executed. In this case, the mode selection can be executed by the display-operation section  32 . 
     The supply method of granular material of the embodiment as one example of the supplying mode which is executed using the supplying apparatus  1  of the embodiment is not limited to the above and other variations are possible. The supply method is not limited to the configuration using the supplying apparatus  1  of the embodiment of the present invention and can be executed using other supplying apparatus of various configurations. 
     In the above examples, the storage container  10  is approximate in the shape of a square on the plan view, but it can be in the shape of other polygons or of approximate circles. 
     In addition, in the above examples, the valve body  21  of the supplying portion  20  is approximately cylindrical, but it can be an approximately polygonal column. 
     In the above examples, the closing portion  25  of the valve body  21  is provided for the outer side of the storage container  10  further than the material supplying passage  22  in the axial direction of the valve body  21 ; however, it can be provided for the inner side of the storage container  10  further than the material supply passage  22  in the axial direction of the valve body  21 . Namely, the material supplying passage  22  can be provided outside the storage container  10  at the closed position of the valve body  21 . 
     In the above examples, the material supplying passage  22  is approximately circular seen in the penetrating direction; however, it can be approximately a square or other polygonal shapes. 
     In the above examples, the material supplying passage  22  is gradually enlarged in diameter toward the outlet  24 ; however, the entire material supplying passage  22  can be approximately the same in diameter along the axial direction of the material supplying passage  22 . 
     In the above examples, the outlet  24  also opens in the storage container  10  when the valve body  21  is at the open position; in place of such an example, the outlet  24  is not required to open in the storage container  10  when the valve body  21  is at the open position. 
     In the above examples, the valve body  21  moves in the vertical direction to be opened or closed; however, the valve body  21  can move in the horizontal direction or in the oblique direction to be opened or closed. 
     In the above examples, the valve body driving section  27  is provided in the storage container  10 ; however, the valve body driving section  27  can be provided outside the storage container  10 . In such a case, the rod  28  of the valve body driving section  27  can be coupled to the outer end, i.e., the lower end, in the axial direction of the valve body  21 . 
     In the above examples, the inlet  23  and the outlet  24  of the valve body  21  open on the side circumferential face  21   a  of the valve body  21 . In place of such an embodiment, the outlet  24  can be configured to open on the outer end face (the lower end face) in the axial direction of the valve body  21 . In such a case, the container tube can be provided in the storage container  10  so as to house the valve body  21  and close the inlet  23 . The valve body  21  is not limited to be tubular or columnar and any shapes are applicable as far as the open and close operations are controlled by the control section  31  and the above-mentioned supplying mode is executed. The specific configurations of the members and parts of the supplying apparatus  1  of the embodiment of the present invention are not limited to those mentioned above and various modifications are possible. 
     REFERENCE SIGNS LIST 
     
         
           1  supplying apparatus of granular material 
           10  storage container 
           17  guide hole 
           21  valve body 
           22  material supplying passage 
           25  closing portion 
           31  control section 
           7  measuring container 
           8  detecting section