JP3208807U - Grain dryer weight measuring structure and grain dryer including the structure - Google Patents

Abstract

The present invention provides a grain dryer weight measurement structure including an upper deformation tension seat and a lower deformation tension seat, and a grain dryer including the weight measurement structure. The tension rod is fixed to the upper deformation tension seat so that the length of the upper end portion in the longitudinal direction is adjustable, the pressure sensor is fixed to the lower deformation tension seat, and the tension rod is lower end of the tension rod. The part is fixed to the pressure sensor by a fine adjustment screw, and the weight measuring structure is fixed to the support column of the base of the dryer I. Therefore, it has advantages such as easy installation, maintenance, and replacement, and is suitable for continuous and circulating dryers. [Selection] Figure 1

Description

  The present invention relates to an apparatus for measuring weight, and more particularly, to a weight measuring structure of a grain dryer and a grain dryer including the structure.

  In grain drying processes, on-line moisture detection is critical for accurate control during the drying process. The existing moisture detection and control methods for grain drying are often realized by the resistance method and the volume method, and have the disadvantages of poor stability and low accuracy, and moisture detection in complex situations. Can't fully meet the needs of In China Patent Application Publication Number CN103388693A, the double connection hole / cantilever type weighing sensor is used as the detection element, and the dry material is sampled online and weighed to determine the absolute value of the measurement error relative to the residual moisture content of the material. An on-line moisture monitoring device in a process of freezing and drying fruits and vegetables that can be controlled within 0.5% is disclosed. Chinese Patent Application Publication No. CN101736565A discloses a clothes dryer having a weight detection device and a method for controlling the dryer using the device. Chinese Patent Application Publication No. CN103483863A discloses an automatic control system for a dryer using a gas jet that measures and controls moisture by a weight sensor. In each of the above patents, weight measurement is a means for detecting moisture. However, since the weight measurement sensor is disposed in the lower part of the material tray or the drying chamber inside the drying equipment, subsequent maintenance is performed. This is disadvantageous for attaching and detaching, and is not particularly applicable to on-line moisture detection by grain drying equipment.

  In the above patents, the weight measurement method is used as a moisture detection method and is applied to control the drying equipment, so that the moisture content rate and the moisture loss rate in the drying process of the dried material are monitored online and Control can be performed accurately and intuitively. For grain drying equipment, this method may be applied to moisture detection and control in the grain drying process, but the installation and maintenance of the weighing sensor is an important issue in the application of this method.

  Applicant has filed Chinese Patent Application No. 2013106825977.8 for a circulating grain dryer. For this purpose, an on-line moisture detection / control method and system based on total weight detection have been proposed, and in its application, an effect superior to the performance of the conventional circulating dryer detection / control method was obtained. However, in this device, since the conventional weight measuring sensor is directly used and installed on the base of the dryer as an on-line moisture detection device by weight, there is still a disadvantage that it is inconvenient to install and maintain.

  In the weight measuring structure of a grain dryer including an upper deformation tension seat and a lower deformation tension seat, a tension rod is adjustably fixed to the upper deformation tension seat, and an upper end portion of the tension rod is fixed to the upper deformation tension seat. The pressure sensor is fixed to the lower deformation tension seat, and the lower end portion of the tension rod is fixed to the pressure sensor by a fine adjustment screw.

  More preferably, it further includes a protective cover for hermetically sealed dust that is fixedly connected to the upper deformation tension seat and the lower deformation tension seat, or is fixed to a stand column of the base of the dryer.

  More preferably, the lower deformation tension seat is provided with a protective screw, and there is a gap between the protective screw and the pressure sensor in the vertical direction.

  Further preferably, the tension rod passes through the upper deformation tension seat by its threaded upper end and is locked with nuts on both sides of the upper deformation tension seat.

  More preferably, the fine adjustment screw is a knurled flat head screw, and is screwed into the screw hole of the pressure sensor so as to be adjustable.

  In the grain dryer including the weight measuring structure of the grain dryer, the weight measuring structure is fixed to a column of the base of the dryer.

  More preferably, the support column is a cylindrical steel pipe.

  Further preferably, the support column is a channel steel or a work steel.

  More preferably, the upper deformation tension seat and the lower deformation tension seat clamp the cylindrical steel pipe by a double locking active seat.

  More preferably, the upper deformation tension seat and the lower deformation tension seat are fixed to the grooved steel or the engineering steel by welding.

  The grain dryer weight measurement structure of the present application has advantages such as easy installation, maintenance, and replacement, and is suitable for continuous and circulating dryers, and has the effect of low maintenance cost and good fixation. .

It is a schematic diagram of a structure of the continuous dryer which concerns on this invention. It is the schematic diagram (the 1) of the deformation | transformation tension structure of the support | pillar of the cylindrical steel pipe which concerns on this invention. It is the schematic diagram (the 2) of the deformation | transformation tension structure of the support | pillar of the cylindrical steel pipe which concerns on this invention. It is the elements on larger scale of the pressure sensor of this invention. It is the schematic diagram (the 1) of the deformation | transformation tension | tensile_strength structure of the columnar steel pillar which concerns on this invention. It is the schematic diagram (the 2) of the deformation | transformation tension | tensile_strength structure of the columnar steel pillar which concerns on this invention. It is the schematic diagram (the 1) of the deformation | transformation tension | tensile_strength structure of the column of the structural steel which concerns on this invention. It is the schematic diagram (the 2) of the deformation | transformation tension | tensile_strength structure of the column of the structural steel which concerns on this invention. It is a schematic diagram of the circuit structure of the dryer which concerns on this invention. It is a schematic diagram of attachment of the circulation type dryer which concerns on this invention.

  Referring to FIGS. 1 and 10, the present invention is a deformed tensile structure attached to a support column of a continuous dryer. When the grain is supplied into the dryer I, the vertical column is deformed in the axial direction due to the action of pressure, and the deformation tension structure has a small amount of deformation as the vertical column is deformed. The deformation is converted into the deformation applied to the pressure sensor by the pressure tension rod in the deformation tension structure in the weight measuring sensor device II. The pressure sensor 6 converts the deformation amount into an electric signal by the signal detection / conversion means III, and transmits the electric signal to the control / display means IV after amplification and conversion of the electric signal. The level indicator V detects the height of the grain in the dryer in real time by means of a continuous level sensor and transmits the data to the control and display means IV for calculating the volume of the grain in the dryer.

  The deformation | transformation tension | tensile_strength structure can be divided into the attachment aspect from which the attachment aspect differs according to the form of the support | pillar of the base of a dryer. As shown in FIGS. 2 and 3, when the vertical column of the base of the dryer is a cylindrical steel pipe, the upper and lower deformed tension seats are connected by a double locking activity seat. That is, the upper and lower deformable tension seats are provided with grooves on the inward surfaces thereof, and the grooves are matched with the outer circumference of the cylindrical steel pipe, thereby being fastened with the bolt 2 and the nut. As shown in FIGS. 5 and 6, when the vertical column of the base of the dryer has a grooved steel structure, the upper and lower deformed tensile seats are connected by a double welded fixed seat. As shown in FIG. 7 and FIG. 8, when the vertical column of the base of the dryer has a construction steel structure, the upper and lower deformed tensile seats are also connected by a double welded fixed seat.

  The dryer weight measurement sensor device II includes several sets of weight measurement sensors mounted on the base column of the dryer main body I. As shown in FIG. 1, preferably, the weight measurement sensor group may be composed of four or more deformed tensile structures having the same principle, structure, size, material, measurement range, and accuracy. The deformation tension structure includes an upper deformation tension seat 3, a lower deformation tension seat 7, a tension rod 4, a pressure sensor 6, a protection screw 8, a fine adjustment screw 9, and a protection cover 5. Among these, the upper deformation tension seat 3 has a main role for fixing the tension rod 4, and the lower deformation tension seat 7 has a main role for fixing the pressure sensor 6. The upper deformation tension seat 3 and the lower deformation tension seat 7 are fixed to the strut 1 of the base of the dryer in the form of a double-locking activity seat, bolts, welding or a fixed seat. The tension rod 4 is a screw rod, the upper end of which is fixedly connected to the upper deformation tension seat 3 by a double nut, and by adjusting the length of the screw rod protruding from the upper deformation tension seat, Adjustment and locking are possible. The pressure sensor 6 is fixed to the lower deformation tension seat 7 with a screw, a screw hole is provided in the cantilever of the pressure sensor 6, and a fine adjustment screw is attached to an urging point with respect to the pressure sensor 6. The fine adjustment screw 9 is a knurled flat head screw and is attached to a screw hole at an urging point with respect to the pressure sensor 6. By adjusting the rotation of the fine adjustment screw 9, the fine adjustment screw extends out of the screw hole or contracts into the screw hole, and by increasing or decreasing the pre-tightening force, the tension rod 4 is moved relative to the pressure sensor. Appropriate pre-tightening force can be applied. When deformation occurs in the base column 1 of the dryer, the tension rod 4 acts on the fine adjustment screw 9 and finally the pressure sensor 6 is deformed. Preferably, in order to prevent the pressure sensor from being damaged due to overload, a protective screw 8 is attached below the urging point with respect to the pressure sensor 6, and the protective screw 8 is a flat head hexagonal screw. It is attached to the deformation tension seat. An appropriate gap remains between the top of the protective screw 8 and the pressure sensor 6. When the pressure sensor 6 is overloaded, the lower end of the cantilever of the pressure sensor 6 is in contact with the protective screw 8, so that the bending deformation of the cantilever of the pressure sensor 6 is further increased. Rather, it will serve to protect the sensor. Preferably, the entire structure is fixed to the stand base 1 of the dryer base, or is covered with a protective cover that can be fixed to the upper and lower deformation tension seats, which can be dust, rain, This is to avoid affecting the measurement accuracy and damaging the instrument due to snow, wind and other factors and due to the clogging of the gap between the pressure sensor and the fixed seat.

  As shown in FIG. 1, when the moisture content of the grains in the dryer main body I causes a change in weight, the amount of deformation of the upright column changes due to an external load action. The upper deformation tension seat 3 and the lower deformation tension seat 7 in the deformation tension structure are fixed to the support column 1 of the base in the form of a double-locking active seat, bolts, welding, or a fixed seat. Although the relative displacement does not occur, the elastic deformation due to the load action of the support column 1 is converted into a minute change in the relative distance between the upper deformation tension seat 3 and the lower deformation tension seat 7, and is fixed to the upper deformation tension seat 3. When the tension rod 4 is applied to the pressure sensor 6 fixed to the lower deformation tension seat 7, the strain sheet in the pressure sensor 6 is elastically deformed, and the resistance value is changed to change the voltage signal via the bridge circuit. The voltage signal is transmitted to the signal detection / conversion means III.

  As shown in FIG. 9, the signal detection / conversion means III collects and converts a voltage signal, an amplification / filtering circuit, an analog / digital conversion circuit, a watchdog circuit, an MCU signal processing circuit, RS485 serial communication circuit.

  An amplifying / filtering circuit is placed in front so as to amplify the signal by removing noise, and connected to the analog-to-digital conversion circuit so as to convert the analog signal into a digital signal receivable by the host device. Then, the MCU signal processing circuit is connected to the analog-digital conversion circuit so as to process the received digital signal. The watchdog circuit is connected to the MCU signal processing circuit so as to prevent a phenomenon such as program lock or loss. Finally, the processed signal is transmitted to the control / display means IV via the RS485 serial communication circuit.

  Here, the voltage signal, after passing through the amplifying / filtering circuit, is filtered for noise, the interference signal is removed, and the signal value is amplified. The filtered and amplified voltage signal is still an analog quantity and cannot be received by the host device. At this time, it is necessary to convert the signal into a digital signal that can be received by the host device by the analog-digital conversion circuit. The digital signal is calculated by an MCU signal processing circuit which is a signal processing circuit of a single chip machine.

  During operation of the MCU system, phenomena such as program loss, memory failure, external interference, or erroneous operation may occur occasionally. As a result, the system entered the death cycle and could not operate normally. It is necessary to add a watchdog circuit, and the basic function of the watchdog circuit is to initialize the program when a problem occurs in the execution of software or the program is disturbed. In this way, the system can be reset immediately when such interference is encountered. Therefore, the stability of the operation of the device itself can be improved to a considerable extent. At this time, the digitized, stable and calculated signal is transmitted to the control / display means IV.

  Referring to FIG. 2, this embodiment is a modification based on the first embodiment, in which the dryer body 1 is a circulation type grain dryer and the operation mode of the dryer is a batch operation. Although not the same as the first embodiment, the same description as in the first embodiment will be omitted. The level indicator V is a switch type. That is, when the grain height inside the dryer is monitored to reach the level indicator height position, the grain supply is stopped, the drying operation is started, and the drying operation is completed before the drying operation is completed. Grain moisture loss weight in the dryer is collected in real time without supplying the cereal.

  The above description of the embodiments is intended to make it easier for those skilled in the art to understand and apply the present invention. It is clear that those skilled in the art can easily make various modifications to these embodiments, and the general principles described herein apply to other embodiments without going through creative labor. Can. Accordingly, the present invention is not limited to the embodiments disclosed herein, but modifications and variations made by those skilled in the art without departing from the scope of the present invention by those disclosed in the present invention. Should be within the protection scope of the present invention.

The present invention provides a weight measuring structure for a dryer with good industrial applicability that can be applied to on-line moisture control of grains and has advantages such as high accuracy and excellent reliability. To do.

Claims (10)

In the weight measuring structure of the grain dryer including the upper deformation tension seat and the lower deformation tension seat,
The tension rod is adjustably fixed to the upper deformation tension seat, the length of the upper end of the tension rod is adjustable from the upper deformation tension seat, and the pressure sensor is attached to the lower deformation tension seat. A weight measuring structure for a grain dryer, wherein the lower end of the tension rod is fixed to the pressure sensor by a fine adjustment screw.   It further includes a protective cover for sealing and dust-proofing, which is fixedly connected to the upper deformation tension seat and the lower deformation tension seat, or is fixed to an upright column of the base of the dryer. The weight measuring structure of the grain dryer according to claim 1.   The weight measurement of the grain dryer according to claim 1 or 2, wherein the lower deformation tension seat is provided with a protective screw, and there is a gap between the protective screw and the pressure sensor in the vertical direction. Construction.   4. The grain drying according to claim 1, wherein the tension rod passes through the upper deformation tension seat by a threaded upper end thereof and is locked with nuts on both sides of the upper deformation tension seat. 5. Machine weight measurement structure.   The weight measuring structure for a grain dryer according to claim 1 or 3, wherein the fine adjustment screw is a knurled flat head screw and is screwed into a screw hole of the pressure sensor in an adjustable manner. In the grain dryer containing the weight measurement structure of the grain dryer in any one of Claim 1 to 5,
The grain dryer is characterized in that the weight measuring structure is fixed to a support column of the dryer.   The grain dryer according to claim 6, wherein the support column is a cylindrical steel pipe.   7. The grain dryer according to claim 6, wherein the support column is a channel steel or a work shape steel.   8. The grain dryer according to claim 7, wherein the upper deformation tension seat and the lower deformation tension seat clamp the cylindrical steel pipe by a double locking activity seat. 9. The grain dryer according to claim 8, wherein the upper deformation tension seat and the lower deformation tension seat are fixed to the channel steel or the work shape steel by welding.

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