JP4514467B2 - Molded product thickness adjustment mechanism - Google Patents

Description

  The present invention relates to a molded product thickness adjusting mechanism in a rotary powder compression molding machine.

  2. Description of the Related Art Conventionally, in a rotary powder compression molding machine, a plurality of mortars are provided on a rotating disk at a predetermined pitch, and upper and lower rivets are slidably held on the upper and lower sides of each mortar. A configuration is widely used in which a powder filled in a die is compression-molded by passing an upper punch and a lower punch inserted between the upper roll and the lower roll.

  In such a rotary powder compression molding machine, in order to manage the thickness dimension of the molded product, it is considered that the thickness dimension of the molded product is automatically measured and the measured value is displayed by a display meter. (For example, refer to Patent Document 1).

In such a rotary powder compression molding machine, in order to adjust the distance between the upper roll and the lower roll, at least one of the upper roll or the lower roll is supported by the eccentric shaft, and the eccentric shaft A configuration is considered in which a worm gear is attached and the upper roll or the lower roll is rotated around the center of the eccentric shaft by rotating a worm meshed with the worm gear (see, for example, Patent Document 2).
JP 50-85661 A Japanese Patent Publication No.49-16386

  Thus, when adjusting the distance between the upper roll and the lower roll, such as when adjusting the thickness dimension of the molded product, a potentiometer is connected to the worm via a gear pair, When the distance from the lower roll is the maximum and minimum within the preset movable allowable range, for example, the output voltage of the potentiometer when the thickness dimension of the molded product is the maximum and minimum is stored, and the intermediate distance Is widely used by linear interpolation using the output voltage of the potentiometer as a parameter. However, since the upper roll or the lower roll is rotated around the center of the eccentric shaft, the height position of the center is not a linear function of the rotation angle of the eccentric shaft. The distance between the rolls is not a linear function of the potentiometer output voltage. That is, if the distance between the upper roll and the lower roll is calculated using the above-described linear interpolation, an error occurs between the actual distance and the display value. Therefore, in the aspect in which the thickness of the molded product is determined by adjusting the distance between the upper roll and the lower roll, it takes time to adjust the thickness of the molded product, and product loss also occurs. In particular, when a product having a small thickness dimension is molded, there is a possibility that the upper and lower heels are close to each other and the product mold is damaged.

  In order to solve the above problems, the present invention devised a method for calculating the thickness dimension of a molded product, and realizes a molded product thickness adjustment mechanism in which the difference between the actual thickness dimension and the displayed value is small. Is.

That is, the molded product thickness adjusting mechanism according to the present invention inserts the tips of the upper and lower eyelids facing each other along the same central axis into the mortar, and in that state, A position in which the powder filled in the die is compression-molded by passing between rolls provided in a pair of upper and lower and moving in a direction approaching each other, and at least one of the pair of upper and lower rolls is decentered from the center Used in a powder compression molding machine configured to be supported by an eccentric shaft, and a roll rotation moving unit for rotating the eccentrically supported roll around the center of the eccentric shaft, and the eccentrically supported roll comprising a roll position detector for detecting a position, and a calculator for calculating the thickness of the molded article the position of the roll detected by the roll position detecting unit as a parameter, said gauge The rotation angle of the eccentrically supported roll and the eccentrically supported when the eccentrically supported roll is closest to the roll paired with this roll within a preset movable allowable range. The rotation angle of the roll and the eccentric support when the roll supported eccentrically and the roll that is eccentrically supported are farthest from the roll paired with the roll within a preset movable allowable range. The position of the roll, and the position of the roll when the roll is at a reference position where a straight line connecting the center of the eccentrically supported roll and the center of the eccentric shaft is perpendicular to the central axis. together are stored in advance, the calculation unit, roll is supported by the eccentric in advance the rolls forming the roll pair set The position of the eccentrically supported roll when it is closest within the movable allowable range or when the eccentrically supported roll is farthest from the roll paired with this roll within the predetermined movable allowable range. for the change from the reference position, the position of the rotational movement has been previously from the reference position ratio as a parameter change from the reference position of the position of the roll which is supported by detected the eccentric by the roll position detector The rotation angle of the roll is calculated, and the thickness dimension of the molded product is calculated as a sine function of the rotation angle.

  With this configuration, the rotation of the eccentrically supported roll from the reference position to the position of the rotational movement destination using the position of the eccentrically supported roll detected by the roll position detecting unit as a parameter. Since the angle is calculated and the thickness dimension of the molded product is calculated as a sine function of the rotation angle, the thickness required for display accuracy is compared with the conventional configuration in which the thickness dimension of the molded product is calculated by linear approximation. Molding of products with small dimensions can be safely performed by a rotary powder compression molding machine.

Further, the rotation angle of the eccentrically supported roll when the eccentrically supported roll is closest to the roll paired with the roll within a preset movable allowable range, and The position of the roll supported eccentrically, the rotation angle of the roll and the eccentricity when the roll supported eccentrically moves farthest from a roll paired with the roll within a predetermined movable allowable range. The position of the roll supported in advance and the position of the roll in the case where the eccentric supported roll is in the reference position are stored in advance, and the calculation section is eccentrically supported by the roll. Is the closest to the roll paired with this roll within the preset allowable range of movement, or the eccentric Detected by the roll position detection unit with respect to a change from the reference position of the position of the eccentrically supported roll when the roller moves farthest from a roll paired with the roll within a predetermined movable allowable range. since so as to calculate the rotation angle of the roll is supported by the eccentric ratio of a change from the reference position of the position of being supported by the eccentric rolls as a parameter, and is supported by the eccentric rolls The rotation angle can be easily obtained by interpolation calculation , and therefore, such a molded product thickness adjusting mechanism can be suitably realized .

  As a configuration for further reducing the error of the molded product thickness adjustment mechanism, the thickness of the molded product when the roll supported by the calculation unit is in the reference position, and the eccentricity of the molded product is adjusted. The thickness dimension of the molded product when the roll supported by the roll is farthest from the roll paired with the roll within the preset movable allowable range, and the distance between the center of the eccentric supported roll and the eccentric shaft The eccentrically supported roll when the eccentrically supported roll is the farthest distance within the preset movable allowable range from the roll paired with the roll as a parameter of the amount of eccentricity that is the distance between While calculating the rotation angle, the thickness dimension of the molded product when the eccentrically supported roll is at the reference position, the eccentricity The thickness dimension of the molded product when the roll supported by the roll is closest to the roll paired with this roll within the preset movable allowable range, and the distance between the center of the eccentric supported roll and the eccentric shaft Of the roll supported eccentrically in the case where the roll supported eccentrically as a parameter is closest to the roll paired with this roll within a preset movable allowable range. An example in which the rotation angle is calculated is given. This is because, by using the measured value of the eccentric amount of the roll supported eccentrically as a parameter, the influence of the error of the eccentric amount of the roll itself can be eliminated.

  As a configuration capable of easily realizing such a molded product thickness adjusting mechanism, the roll rotation moving unit includes a worm wheel concentrically connected to the eccentric shaft and a worm meshing with the worm wheel, and the roll The position detection unit is configured using a potentiometer connected to the worm via a gear pair, and the output voltage of the potentiometer is used as a parameter indicating the position of the roll.

As described above, according to the molded product thickness adjusting mechanism according to the present invention, the position of the eccentrically supported roll detected by the roll position detecting unit is used as a parameter to support the eccentrically. The straight line connecting the center of the roll and the center of the eccentric shaft is decentered from the reference position in a state perpendicular to the central axis of the upper and lower eyelids arranged along the same central axis to the rotational destination. Since the rotation angle of the supported roll is calculated and the thickness dimension of the molded product is calculated as a sine function of the rotation angle, the display is compared with the conventional configuration in which the thickness dimension of the molded product is calculated by linear approximation. Molding of a product with a small thickness dimension that requires high accuracy can be safely performed by a rotary powder compression molding machine.
Further, the rotation angle of the eccentrically supported roll when the eccentrically supported roll is closest to the roll paired with the roll within a preset movable allowable range, and The position of the roll supported eccentrically, the rotation angle of the roll and the eccentricity when the roll supported eccentrically moves farthest from a roll paired with the roll within a predetermined movable allowable range. The position of the roll supported in advance and the position of the roll in the case where the eccentric supported roll is in the reference position are stored in advance, and the calculation section is eccentrically supported by the roll. Is the closest to the roll paired with this roll within the preset allowable range of movement, or the eccentric Detected by the roll position detection unit with respect to a change from the reference position of the position of the eccentrically supported roll when the roller moves farthest from a roll paired with the roll within a predetermined movable allowable range. Since the rotation angle of the eccentrically supported roll is calculated using the ratio of the change of the position of the eccentrically supported roll from the reference position as a parameter, the eccentrically supported roll The rotation angle can be easily obtained by interpolation calculation, and therefore, such a molded product thickness adjusting mechanism can be suitably realized .

  A preferred embodiment of the present invention will be described below with reference to FIGS.

  The rotary powder compression molding machine according to this embodiment has a configuration similar to that of a known rotary powder compression molding machine conventionally used, for example, the one described in Japanese Patent No. 2519855. That is, the rotary powder compression molding machine 100 can horizontally rotate the rotating disk 3 in the frame 1 through the vertical shaft 2 as shown in the sectional view in FIG. 1 and the outline of the main part in FIG. A plurality of mortars 4 are provided on the rotating disk 3 at a predetermined pitch, and upper and lower barbs 5 and 6 are held slidably on the upper and lower sides of each mortar 4. The upper rod 5 and the lower rod 6 are disposed to face each other along the central axis L0 extending in the same vertical direction. Then, with the upper end 5 and the lower end 6 inserted into the mortar 4 with their respective tips inserted into the mortar 4, first, the pre-compression upper roll (not shown) and the lower roll (not shown) are passed. Later, the powder filled in the die 4 is compression-molded by passing between the upper roll 82 and the lower roll 92 for main compression and moving so as to be close to the direction along the central axis L0, that is, the vertical direction. Is getting. A powder filling mechanism 7 for filling powder into the mortar 4 is attached from above the rotating disk 3 toward the rotating disk 3.

  An upper roll and a lower roll for preliminary compression, and an upper roll 82 and a lower roll 92 for main compression are respectively paired up and down, and an upper roll or a lower roll for preliminary compression with respect to the rotation direction of the turntable 3. In this order, the upper roll 82 or the lower roll 92 for main compression is arranged with an angle of 67 degrees, for example.

In this embodiment, as shown in the front view in FIG. 3, the plan view in FIG. 4, and the side view in FIG. 5, the main compression lower roll 92 is supported by the eccentric shaft 90, and the roll The molded product thickness adjusting mechanism 10 further includes a rotational movement unit 101, a potentiometer 102 serving as a roll position detection unit, a sequencer 103 serving as a calculation unit, and a display unit 104. The molded product thickness adjusting mechanism 10 rotates the main compression lower roll 92 around the center of the eccentric shaft 90 so that the main compression is a roll eccentrically supported by the eccentric shaft 90. The state in which the lower roll 92 for use is closest to the upper roll 82 for main compression, which is a roll paired with the lower roll 92 for main compression, within the preset movable allowable range, that is, (a) of FIG. and state thickness Y of the molded article as shown is the minimum thickness Y _1, on a roll for the compression paired with lower roll 92 of the lower roll 92 for the compression for the said main compression farthest state within the movable permissible range set in advance from 82, i.e. continuously changed between the state thickness Y of the molded article as shown in FIG. 6 (b) is the maximum thickness dimension Y ₂ To let Forms.

The center C0 of the eccentric shaft 90 is displaced from the center C1 of the main compression lower roll 92 by an eccentric amount E, as shown in FIG. The eccentric shaft 90, when the thickness Y of the molded article is a minimum thickness dimension Y ₁ is the as shown in (a) of Figure 6, eccentric with the center C1 of the lower roll 92 for the compression a position straight line L1 connecting the center C0 of the shaft 90 is rotated by an angle T _L on the side to reduce the thickness Y of the molded article from the reference position in a state that is perpendicular to the center axis L0. On the other hand, when the thickness Y of the molded article is a maximum thickness dimension Y _2, as shown in (b) of FIG. 6, on the side of increasing the thickness Y of the molded article from the reference position a position rotated by an angle T _H. Then, by continuously changing the position of the eccentric shaft 90 between these two positions, the main compression lower roll 92 supported by the eccentric shaft 90 rotates around the center of the eccentric shaft 90. moved by changing the height position of the points the lower punch 6 abuts against the lower roll 92 for the main compression, the minimum thickness dimension Y of the molded article thickness Y ₁ and a maximum thickness dimension as described above and configured to continuously vary between Y _2. Here, in this embodiment, instead of directly indicating the distance between the upper roll 82 for main compression and the lower roll 92 for main compression, in order to make it easy for the operator to operate the molded product thickness adjustment mechanism 10, When the upper collar 5 and the lower collar 6 pass between the upper roll 82 for main compression and the lower roll 92 for main compression, the distance between the upper collar 5 and the lower collar 6 is minimized. The distance between the upper surface of the collar 6 and the lower surface of the upper collar 5, that is, the thickness dimension Y of the molded product is shown.

The roll rotation moving unit 101 includes a worm wheel 1011 provided on the eccentric shaft 90 and a worm 1012 engaged with the worm wheel 1011. The eccentric shaft 90 also rotates as the worm 1012 rotates, and the thickness dimension Y of the molded product is minimized by rotating the lower roll 92 for main compression around the center of the eccentric shaft 90 as described above. and configured to continuously vary between the thickness dimension Y ₁ and a maximum thickness dimension Y _2. The power for rotating the worm 1012 is supplied from a motor (not shown) connected to the worm shaft 1013.

  The potentiometer 102 has the same configuration as that of a potentiometer that has been widely used in the past, and is connected to the worm 1012 via a gear pair 1021 so that the resistance value changes as the worm 1012 rotates. It is configured. The output voltage of the potentiometer 102 (hereinafter referred to as an output value X) uniquely corresponds to the position of the main compression lower roll 92 that rotates as the worm 1012 operates. Here, the gear pair 1021 is configured by meshing a gear connected to the worm shaft 1013 and a gear connected to the input shaft of the potentiometer 102. In this embodiment, the potentiometer 102 is known as a multi-rotation type potentiometer in order to improve accuracy, that is, in order to change from a state where the resistance value is minimum to a state where the resistance value is maximum. What needs to be rotated is used. Moreover, you may make it use apparatuses other than this potentiometer 102 as a roll position detection part.

As shown in FIG. 3, the sequencer 103 includes at least a CPU 1031 such as a microprocessor, an input / output interface 1032, and an internal memory 1033. The input / output interface 1032 is connected to the roll rotation moving unit 101, the potentiometer 102, and the display unit 104, and receives the output value X of the potentiometer 102. A signal for rotating the lower roll 92 and a signal for visualizing and displaying the thickness Y of the molded product on the display unit 104 are output. The first predetermined area of the internal memory 1033, the thickness Y _c of the molded article at the reference _position, the minimum of the molded article thickness Y _1, the maximum thickness dimension Y _2, and the eccentric amount of the molded article E is stored in advance. Further, from the second prescribed regions, the reference position of the lower roll 92 of the output value X ₁ and the compression of the potentiometer when the thickness of the molded article is minimized thickness Y ₁ of the internal memory 1033 the rotation angle T _L of the rotation angle T _H from the reference position of the output values X ₂ and the lower roll 92 for the compression of the potentiometer when the thickness of the molded product becomes the maximum thickness dimension Y _2, the A constant calculation storage program for calculating and storing the output value _Xc of the potentiometer when the lower roll 92 for compression is located at the reference position is stored. Further, the third predetermined area of the internal memory 1033 stores a program for calculating the thickness dimension Y of the molded product using the output value X of the potentiometer 102 as a parameter indicating the position of the main compression lower roll 92. is doing. In the fourth predetermined area of the internal memory 1033, the thickness dimension Y of the molded product is compared with the target thickness dimension YY which is the thickness dimension of the desired molded product, and the thickness dimension Y of the molded product is compared. Stores a program for controlling the roll rotation moving unit 101 so as to be the target thickness dimension YY.

  In the present embodiment, the display unit 104 is configured using a touch panel connected to the sequencer 103. The display unit 104 receives a signal from the sequencer 103 and receives a signal from the sequencer 103 as a result of calculation by the sequencer 103. The thickness dimension Y is visualized and displayed. The display unit 104 functions as a target thickness input unit that receives an input of a target thickness dimension YY that is a thickness dimension of a desired molded product in cooperation with the sequencer 103.

  A specific procedure for calculating the thickness dimension Y of the molded product through the sequencer 103 will be described below.

  The sequencer 103 executes the above-described constant calculation storage program prior to execution of the program for calculating the thickness dimension Y of the molded product using the output value X of the potentiometer 102 as a parameter. A procedure of processing performed by the constant calculation storage program will be described below with reference to FIG. 7 which is a flowchart.

In step S11, _TL is calculated by the following formula 1, and the process proceeds to step S12.

T _L = sin ⁻¹ [(Y _c −Y ₁ ) / E] (1)
In step S12, the state thickness Y of the molded article is minimal, i.e. Y = on the lower roll 92 for the compression through the roll rotational movement section 101 until the state is a Y ₁ for the compression Move in a direction to approach the roll 82. Thereafter, the process proceeds to step S13.

In step S <b> 13, the potentiometer output value X <b> ₁ when the thickness dimension Y of the molded product is minimized is stored in the sequencer 103. Next, the process proceeds to step S14.

In step S14, the equation 2 shown below, to calculate the _{T H,} the process proceeds to step S15.

T _H = sin ⁻¹ [(Y ₂ −Y _C ) / E] (2)
In step S15, the roll rotating state thickness Y of the moving portion 101 via a molded article is at a maximum, i.e. Y = Y until the state is _two on the lower roll 92 for the compression for the compressed Move in a direction away from the roll 82. Thereafter, the process proceeds to step S16.

In step S < _b > 16, the potentiometer output value X < _b > ₂ when the thickness dimension of the molded product is maximized is stored in the sequencer 103. Next, the process proceeds to step S17.

In step S17, the output value _Xc of the potentiometer 102 when the lower roll 92 for main compression is located at the reference position is calculated by the following formula 3.
_{X C = X 1 + (X} 2 -Y 1) × (Y C -Y 1) / (Y 2 -Y 1) (3)
In the present embodiment, the above-described constants are obtained by the constant calculation storage program described above, and the output values X ₁ and X ₂ of the potentiometer when the thickness dimension of the molded product is minimum or maximum are measured. with T _L, T _H, and is a X _c so that calculated on the basis of the measured values of X _1, X _2, each of these constants also be allowed to pre-stored values are mechanically designed Good.

  The flow of processing performed by the molded product thickness adjusting mechanism 10 when adjusting the thickness Y of the molded product to be the target thickness YY that is the desired thickness of the molded product is shown in the flowchart. The following will be described with reference to FIG.

  First, in step S21, the input of the target thickness dimension YY is accepted via the target thickness input unit.

  Next, in step S <b> 22, the sequencer 103 receives the output value X from the potentiometer 102.

Then, in step S23, the magnitude relationship between the output value X and the output value _Xc of the potentiometer 102 at the reference position is determined. If the output value X is smaller than the output value _Xc of the potentiometer 102 at the reference position in step S22, the process proceeds to step S24, and if not, the process proceeds to step S25.

  In step S24, the rotation angle T of the main compression lower roll 92 is calculated according to the following mathematical formula 4. Thereafter, the process proceeds to step S26.

_{T = T L × (X C} -X) / (X C -X 1) (4)
In step S25, the rotational angle T of the lower roll 92 for main compression is calculated by the following formula 5. Thereafter, the process proceeds to step S26.

_{T = T H × (X C} -X) / (X 2 -X C) (5)
In step S26, the thickness dimension Y of the molded product is calculated according to Equation 6 shown below.

Y = Y _C -EsinT (6)
In step S27, the thickness Y of the molded product calculated in step S26 is visualized and displayed via the display device 104.

  In step S28, the thickness dimension Y of the molded product calculated in step S26 is compared with the target thickness dimension YY. In step S28, when the thickness dimension Y of the molded product coincides with the target thickness dimension YY, step S29, and when the thickness dimension Y of the molded product is larger than the target thickness dimension YY, step S30. When the thickness dimension Y of the molded product is smaller than the target thickness dimension YY, the process proceeds to step S31.

  In step S29, control is performed to fix the position of the lower roll 92 for main compression via the roll rotation moving unit 101, and the process is terminated.

  In step S30, the main compression lower roll 92 is moved in the direction approaching the main compression upper roll 82 via the roll rotation moving unit 101. Thereafter, the process returns to step S22.

  In step S31, the main compression lower roll 92 is moved away from the main compression upper roll 82 via the roll rotation moving unit 101. Thereafter, the process returns to step S22.

  Note that the thickness dimension of the molded product may be adjusted by a method other than those described above. The flow of an example of processing performed by the molded product thickness adjusting mechanism 10 when adjusting the thickness dimension of the molded product will be described below.

  First, a button for receiving a command for increasing the thickness dimension of the molded product (hereinafter referred to as a thickness dimension increasing button) and a button for receiving a command for decreasing the thickness dimension of the molded product (hereinafter referred to as thickness). (Referred to as dimension reduction button). Next, when an input to the thickness dimension increasing button is performed, control is performed to move the main compression lower roll 92 away from the main compression upper roll 82 via the roll rotation moving unit 101. Do. On the other hand, when an input to the thickness dimension reduction button is performed, the main compression lower roll 92 is moved in the direction of approaching the main compression upper roll 82 via the roll rotation moving unit 101. And control similar to step S22-step S27 mentioned above is performed. In this case, the operator of the molded product thickness adjusting mechanism 10 visually observes the thickness dimension Y of the molded product visualized and displayed in step S27, and the thickness dimension Y of the molded product becomes a desired thickness dimension. Until the thickness dimension increase button and the thickness dimension decrease button are operated.

  The change of the thickness Y of the molded product calculated and displayed in this way with respect to the output value X of the potentiometer 102 is indicated by the solid line in FIG. 9 and the molded product visualized and displayed by the conventional molded product thickness adjusting mechanism. The change of the thickness dimension Y with respect to the output value X of the potentiometer 102 is indicated by a broken line in FIG. Conventionally, since the change of the thickness dimension Y of the molded product with respect to the output value X of the potentiometer 102 is approximated by a straight line, the thickness dimension Y of the molded product, which is a sine function of the rotation angle of the lower roll 92 for compression. An error sometimes occurred. On the other hand, in the configuration described above, the rotation angle of the lower roll 92 for main compression is calculated using the output value X of the potentiometer as a parameter, and the thickness dimension Y of the molded product is calculated using this rotation angle as a parameter. Therefore, the occurrence of errors based on the approximation as described above can be suppressed.

  As described above, the molded product thickness adjusting mechanism 10 according to the present application uses the sine function of the output value of the potentiometer 102 serving as the roll position detection unit to allow the sequencer 103 serving as the calculation unit to change the thickness Y of the molded product. Thus, the difference between the calculated thickness Y of the molded product and the actual thickness of the molded product can be reduced as compared with the conventional one using only linear interpolation. Accordingly, the rotary powder compression molding machine 100 can safely and reliably form a product with a small thickness dimension that requires display accuracy.

Further, the rotation angle T _L from the reference position of the lower roll 92 of the output value of the potentiometer X ₁ and the compression when the thickness of the molded article is minimized thickness Y _1, thickness of the molded article If There positioned on the rotation and angle T _H, the reference position is lower roll 92 for the compression from the reference position of the lower roll 92 of the output value of the potentiometer X ₂ and the compression in the case of the maximum thickness dimension Y ₂ The sequencer 103 executes in advance a constant calculation storage program for calculating and storing the output value _Xc of the potentiometer, and using the potentiometer output value X as a parameter according to the above-described Expression 4 or Expression 5. Since the rotation angle T from the reference position of the lower roll 92 for compression is obtained, the rotation angle of the lower roll 92 for compression is quickly obtained by interpolation calculation. Can.

  The roll rotating unit 101 includes a worm wheel 1011 concentrically connected to the eccentric shaft 90 and a worm 1012 meshing with the worm wheel 1011, and the roll position detecting unit 102 is connected to the worm 1012 and a gear. The potentiometer 102 connected via the pair 1021 is used, and the output value X of the potentiometer 102 is used as a parameter indicating the position of the lower roll 92 for main compression. The position of the lower roll 92 for main compression can be obtained as the output value X of the potentiometer 102.

  The present invention is not limited to the embodiment described above.

  For example, in the above-described embodiment, the eccentricity amount E is stored in advance in the sequencer. However, the input of the measured value of the eccentricity amount E is prompted at the first activation, and the input measured value of the eccentricity amount E is a sequencer that is a calculation unit. May be stored in advance. In this way, it is possible to eliminate the influence of the error of the eccentricity itself on the calculated thickness value of the molded product, so it is possible to obtain a more accurate calculated value of the molded product thickness dimension and visualize it. Will be able to.

  Further, the rotation of the worm may be performed manually. Further, instead of connecting the worm wheel to the eccentric shaft, a rotating arm is fixed to the eccentric shaft, for example, as described in Japanese Patent Publication No. 7-106474, and the rotating end of the rotating arm is connected to a spherical bearing. You may employ | adopt the structure connected to the advancing / retreating axis | shaft of a shock absorber via a universal joint of a type | formula.

  Further, the thickness adjusting mechanism of the molded product as described above may be adopted not only for the main compression roll but also for the preliminary compression roll. In this way, the thickness can be accurately displayed during the preliminary compression, so that the strength of the preliminary compression can be adjusted safely and reliably.

Sectional drawing which shows the rotary powder compression molding machine which concerns on one Example of this invention. The figure which shows the principal part of the rotary powder compression molding machine in the Example. The front view of the molded product thickness adjustment mechanism in the Example. The top view of the molded product thickness adjustment mechanism in the Example. The side view of the molded product thickness adjustment mechanism in the Example. The figure which shows the effect | action of the molded article thickness adjustment mechanism in the Example. The figure which shows the flow of the process which the molded article thickness adjustment mechanism in the Example performs. The figure which shows the flow of the process which the molded article thickness adjustment mechanism in the Example performs. The figure which shows the relationship with respect to the output value of the potentiometer of the thickness dimension of the molded article in the Example.

Explanation of symbols

DESCRIPTION OF SYMBOLS 10 ... Molded product thickness adjustment mechanism 101 ... Molded product thickness adjustment mechanism 102 ... Potentiometer (roll position detection part)
103 ... Sequencer (calculation unit)
104 ... Display unit 82 ... Upper roll 92 ... Lower roll

Claims (3)

Insert the tip of the upper and lower punches, which are placed opposite to each other along the same central axis, into the mortar, and pass the upper and lower punches between the upper and lower rolls in this state, approaching each other. Used in a powder compression molding machine having a configuration in which at least one of the pair of upper and lower rolls is supported by an eccentric shaft at a position eccentric from the center thereof. And
A roll rotation moving unit that rotates and moves the eccentrically supported roll around the center of the eccentric shaft, a roll position detecting unit that detects a position of the eccentrically supported roll, and the roll position detecting unit A calculation unit for calculating a thickness dimension of a molded product using the detected position of the roll as a parameter,
The rotation angle and the eccentricity of the eccentrically supported roll when the eccentrically supported roll is closest to the roll paired with the roll within the preset movable allowable range. The position of the roll supported by the roll and the rotation angle of the roll and the eccentric support when the roll supported by the eccentric is farthest from a roll paired with the roll within a preset movable allowable range. The position of the roll when the roll is at a reference position in which a straight line connecting the position of the rolled roll and the center of the eccentrically supported roll and the center of the eccentric shaft is perpendicular to the central axis Are stored in advance,
When the calculation unit is closest to the roll paired with the roll within a predetermined movable allowable range, or the roll paired with the roll is paired with the roll. Of the eccentrically supported roll detected by the roll position detection unit with respect to a change from the reference position of the position of the eccentrically supported roll when moving farthest within a predetermined movable allowable range from The rotation angle of the roll from the reference position to the previous position rotated by using the ratio of the change of the position from the reference position as a parameter is calculated, and the thickness dimension of the molded product is calculated as a sine function of the rotation angle. A molded product thickness adjusting mechanism characterized in that The thickness of the molded product when the eccentrically supported roll is at a reference position, the movable allowable range set in advance from the roll that the eccentrically supported roll is paired with this roll The thickness of the molded product when moving farthest and the amount of eccentricity, which is the distance between the center of the eccentrically supported roll and the distance of the eccentric shaft, are used as the parameters to support the eccentrically supported roll. While calculating the rotation angle of the eccentrically supported roll when moving farthest from the roll paired with this roll within a preset movable allowable range, the eccentrically supported roll is The thickness dimension of the molded product when it is in the reference position, the movable tolerance set in advance for the roll that the eccentric supported roll makes a pair with this roll A roll that is eccentrically supported using the thickness dimension of the molded product when closest in the enclosure and the amount of eccentricity that is the distance between the center of the eccentrically supported roll and the distance of the eccentric shaft as parameters. molding according to claim 1, characterized in that in way to calculate the rotation angle of the roll is supported by the eccentric when the closest in this role paired within the movable tolerance ranges preset in roll forming the Product thickness adjustment mechanism. A potentiometer in which the roll rotation moving unit includes a worm wheel concentrically connected to the eccentric shaft and a worm meshing with the worm wheel, and the roll position detecting unit is connected to the worm via a gear pair. constructed by using the output voltage of the potentiometer, the molded article thickness adjusting mechanism according to claim 1 or 2, characterized in that as a parameter indicating the position of the roll.

Images