JP6372841B1 - Vacuum drying equipment - Google Patents

Abstract

[PROBLEMS] To reduce drying costs by reducing drying time, reducing the size of the device, reducing vibration noise during operation, and reducing the environmental load by eliminating the oil collected in the rotary cylinder device. Provided is a vacuum drying apparatus that can be used at home. At least one cylinder among a plurality of cylinders into which a pair of double-headed piston sets 23 and 24 is slidably inserted is connected to a vacuum drying container 4 in which an object to be dried W is stored. 5, the remaining cylinder is used as a pressure difference generating cylinder 6 that generates a pressure difference between the inside and outside of the case body 3, and a positive or negative pressure is applied to the piston head portion 24 b that reciprocates in the evacuating cylinder 5. Seal cups 24c1 and 24c2 are provided to stand with respect to the end surface of the piston head portion 24b in any direction. [Selection] Figure 1

Description

  The present disclosure relates to a vacuum drying apparatus using a rotary cylinder device that converts a rotational motion of a drive shaft into a linear reciprocating motion of a piston in a cylinder.

  Dryers are used in factories, offices, hospitals, and canteens to reduce the volume of food waste (garbage, food residues, etc.), laundry, and various materials. The drying method of the drying apparatus is roughly classified into a hot air drying method or a vacuum drying method, except for those by natural drying or chemical drying. In general, the hot air drying method has a high drying cost, and the drying apparatus itself tends to be large and complicated. Therefore, hereinafter, a vacuum drying apparatus having a low drying cost will be described.

  Garbage and food residues generated in ordinary households and small and medium-sized food business operators are collected and burned every few days as combustible waste from local governments. Combustible waste becomes a serious problem in urban apartments and condominiums because it decays and emits a bad odor at high temperatures such as in the summer, and the amount of water consumed during incineration is high. There is a problem of increasing. However, the reality is that vacuum drying devices that dry and reduce food waste and food residues are not widely used in general households and small and medium-sized food business operators. The reasons may be that the drying cost including the initial investment is high, the drying time is long, the installation area of the drying apparatus is large and there is no storage space, and the operation sound is large.

There are two main types of medium-sized and small-sized vacuum dryers, excluding large-sized vacuum dryers used for industrial use, diaphragm type vacuum pumps or oil rotary type vacuum pumps (vane type).
The diaphragm type vacuum pump performs intake and exhaust when the rotor rotates to deform the diaphragm through the connecting rod to expand and contract the volume of the pump chamber (Patent Document 1: JP-A-2015-203310). See the official gazette).

  In the oil rotary vacuum pump, a plurality of vanes for partitioning the cylinder chamber are assembled to a rotor that is eccentrically rotated in the cylinder. When the rotor rotates, the plurality of vanes slide while being in contact with the inner wall of the cylinder, and the gas sucked from the intake port is compressed according to the volume change of the cylinder chamber and exhausted from the exhaust valve. Vacuum pump oil is supplied to the inner wall surface of the cylinder to smooth the sliding of the vanes (see Patent Document 2: JP 2006-200506 A, Patent Document 3: JP 2012-1937271 A).

JP-A-2015-203310 JP 2006-200506 A JP 2012-1937271 A

  Qualitatively explaining the drawbacks of the above-described vacuum drying apparatuses, first, the diaphragm vacuum pump (Patent Document 1) has extremely large power consumption and a small suction capacity. In addition, the life of the rubber diaphragm is short (replacement is required after an operation time of 3000 hours), and the operation noise due to mechanical loss due to piston reciprocation is large.

In addition, the oil rotary vacuum pump (Patent Documents 2 and 3) deteriorates pump performance by mixing water into the oil supplied into the pump body. In order to reduce this deterioration, a gas ballast valve for introducing an appropriate amount of outside air into the compression chamber is required, and the suction performance of the vacuum pump is lowered. Moreover, in order to reduce the water | moisture content which enters into the oil supplied in the cylinder, it is necessary to raise pump main body temperature to about 70 degreeC. Moreover, in order to remove the water | moisture content mixed in the oil in a pump main body, the idle driving | running | working of a pump is needed regularly. Furthermore, since some oil is mixed in the water recovered by vacuum drying, it is necessary to take environmental measures for separate collection.
In any method, it is necessary to take environmental measures such as drying cost including drying time, downsizing of the device, generation of vibration and noise during operation, and oilless oil recovered from the vacuum pump. The reality is that it is difficult for small and medium-sized food business operators.

  Disclosure applied to some embodiments described below has been made to solve the above-described problems, and the object of the disclosure is to shorten the drying time, reduce the drying cost, and reduce the size of the apparatus. Another object of the present invention is to provide a vacuum drying apparatus that can be used even in ordinary households by reducing vibration and noise during operation, reducing the environmental load by reducing the amount of oil collected in the rotary cylinder device, and reducing the environmental load.

Disclosure relating to some embodiments described below includes at least the following configurations.
A case main body containing a rotary cylinder device that converts rotation of a drive shaft that is rotationally driven by a drive source into a reciprocating motion of a pair of double-headed piston sets arranged orthogonal to an eccentric cam in accordance with the principle of inner cycloid A vacuum drying apparatus in which a vacuum drying container in which a dried product is stored is connected to a pipe, wherein at least one of a plurality of cylinders provided in the case body into which the pair of double-headed piston sets are slidably inserted. Cylinders are used as evacuation cylinders that are connected to the vacuum drying container in which the objects to be dried are stored and evacuate, and the remaining cylinders generate a pressure difference between the inside and outside of the case body to generate an airflow flowing inside and outside the case body It is used as a pressure difference generating cylinder to be formed, and a positive or negative pressure is applied to the piston head part reciprocating in the vacuuming cylinder. Wherein the seal cup erected against the end surface of the piston head portion with respect to the direction of displacement is provided.

  As described above, the piston head portion reciprocating in the evacuating cylinder is provided with a seal cup that stands up with respect to the end face of the piston head portion in either the positive pressure or negative pressure direction. In addition, it is possible to prevent water droplets generated in the cylinder, which could not be realized by the seal cup used in the conventional vacuum pump, from flowing into the case body. Further, according to the principle of internal cycloid, the rotation of the drive shaft is converted into a reciprocating motion of a pair of double-headed pistons arranged orthogonal to the eccentric cam. By using it as a evacuating cylinder connected to the drying container, it is possible to reduce the size of the pump device for evacuation and reduce mechanical loss caused by the reciprocating motion of the double-headed piston assembly, thereby reducing vibration and noise.

  The pressure difference generating cylinder forms a positive pressure state or a negative pressure state by reciprocating movement of the double-headed piston set, creates a pressure difference inside and outside the case body, and forms an air flow flowing inside and outside the case body. Is preferred. As a result, even if water drops pass through the piston head through the slight unevenness on the inner wall surface of the cylinder and water drops enter the case body from the vacuum drying container side, moisture is evaporated by the airflow flowing inside and outside the case body. It can be discharged outside the main body.

The discharge port connected to the cylinder chamber of the evacuating cylinder is preferably provided so as to include the lower end edge in the gravity direction of the cylinder opening.
As a result, even if water contained in the air sucked into the vacuuming cylinder evacuated from the vacuum drying container is turned into water droplets and flows down to the lower edge in the gravity direction of the cylinder opening of the vacuuming cylinder, it is reliably from the discharge port. It is possible to discharge the water and prevent the water droplets from remaining in the evacuation cylinder.

The vacuum drying container is preferably kept at a predetermined temperature, and the outside air taken into the container is preferably warm air.
As a result, water takes away latent heat when boiling, but if the vacuum drying container is kept at a predetermined temperature, the temperature in the container is prevented from lowering and the drying efficiency is not lowered. Further, when the outside air taken in to promote the convection of the air in the vacuum drying container accompanying the suction of the evacuation cylinder is warm air, it is possible to prevent condensation or a decrease in the temperature in the container. .

  By using the above-described vacuum drying apparatus, the drying time is shortened to reduce the drying cost, the apparatus is downsized, the vibration and noise during operation are reduced, and the oil that is collected in the rotary cylinder device is oilless. By reducing the environmental load, it can be used in ordinary households.

It is an upper perspective view of a vacuum dryer. It is a downward perspective view which shows the drive transmission mechanism of the vacuum dryer of FIG. It is an external appearance perspective view of a rotary cylinder device. FIG. 4 is an axial plan view of the rotary cylinder device of FIG. 3 with a case main body removed, a front view of a seal cup mounted on a piston head, a perspective view, and an arrow YY sectional view. FIG. 4 is an exploded perspective view of the rotary cylinder device of FIG. 3. It is a top view of a rotary type cylinder device, arrow XX sectional view, a front view, and Z section expanded sectional view. It is a front view of a cylinder head part and a head cover. It is the front view of the conventional vacuuming cylinder, arrow YY sectional drawing, and a partial expanded sectional view. It is a graph which shows a water vapor pressure curve. It is a schematic diagram showing the relationship between the rotational trajectory of the first crankshaft centered on the drive shaft, the rotational trajectory of the second crankshaft centered on the first crankshaft, and the linear reciprocating motion of the double-headed piston set.

  Hereinafter, an embodiment for carrying out the invention will be described in detail with reference to the accompanying drawings. First, a vacuum drying apparatus will be described as an example with reference to FIGS. The vacuum drying apparatus 1 reciprocates a pair of double-headed piston sets 23 and 24 arranged orthogonal to the eccentric cam 22 in accordance with the inner cycloid principle by rotating the drive shaft 2a rotated by a motor M (drive source). The rotary type cylinder device 2 is converted into (see FIG. 5). Further, the case body 3 of the rotary cylinder device 2 and the vacuum drying container 4 in which the object to be dried W is stored are connected by piping (see FIG. 1).

  In the following description, an embodiment in which two vacuuming cylinders are provided in the vacuum drying apparatus 1 will be described. In the case body 3 in which a plurality of cylinders into which a pair of double-headed piston sets 23 and 24 are slidably inserted are assembled, at least one cylinder is connected to a vacuum drying container 4 in which an object to be dried W is stored. Used as a pulling cylinder 5. In the present embodiment, a pair of cylinders assembled in the front-rear direction of the case body 3 in FIG. A pair of cylinders assembled in the left-right direction of the case body 3 is used as a pressure difference generating cylinder 6 that generates a pressure difference between the inside and outside of the case body 3.

  In FIG. 1, the apparatus base part 7 is supported horizontally by the both-side leg parts 7a from the installation surface. As shown in FIG. 2, the motor M is supported and fixed on the apparatus base portion 7 so that the motor shaft 8 is arranged in a direction orthogonal to the horizontal plane. Further, the drive shaft 2a of the rotary cylinder device 2 is supported and fixed on the device base portion 7 so as to be arranged in a direction orthogonal to the horizontal plane.

  In FIG. 2, a motor pulley 8 a is assembled to the motor shaft 8. A drive pulley 2b is assembled to the drive shaft 2a. An endless timing belt 9 is installed on the motor pulley 8a and the drive pulley 2b.

  In FIG. 1, the pipe connection structure provided in the rotary cylinder device 2 will be described. The rotary cylinder device 2 (evacuation cylinder 5) and the vacuum drying container 4 are connected by a suction pipe 10. Specifically, the vacuum drying container 4 includes a lid portion 4A and a container body 4B, and the lid portion 4A is provided with a pair of pipe joints 4a. In addition, pipe joints 39 a are provided on the head cover 39 that covers the cylinder head portion 37 of the vacuuming cylinder 5. The pair of pipe joints 4a and the pipe joint 39a are connected to each other by a suction pipe 10. The head cover 39 is provided with a pipe joint 39b, and the discharge pipe 11 is connected vertically downward to the pipe joint 39b.

  A pipe joint 34 a is provided on each head cover 34 that covers the cylinder head portion 32 of the pressure difference generating cylinder 6. The pair of pipe joints 34 a and the pair of pipe joints 13 a connected to the intake pipe 12 are connected to each other by a suction pipe 14. The head cover 34 is provided with a pipe joint 34b, and each pipe joint 34b is connected to each other by a pair of pipe joints 15a and a connecting pipe 16. The pair of pipe joints 15 a is pipe-connected by a pipe joint 3 a provided on the top surface portion of the case body 3 and a connecting pipe 17. In addition, one or a plurality of discharge holes 3b are formed on either side surface of the case body 3. The outside air blown into the case main body 3 from the pressure difference generating cylinder 6 through the connecting pipe 16, the pipe joint 15a, the connecting pipe 17 and the pipe joint 3a is exhausted from the inside of the case main body 3 to the outside through the discharge holes 3b. It is like that.

  Next, the configuration of the vacuum drying container 4 will be described. The vacuum drying container 4 is a metal container, and the container body 4B is preferably provided with heating means such as a heater (not shown). The lid portion 4A is provided with pipe joints 4a and 4b, and the suction pipe 10 is connected to each of the pair of pipe joints 4a. The pipe joint 4b is provided with a pressure adjusting valve 18, an outside air intake pipe 19, and a pressure gauge 20 for measuring the atmospheric pressure in the container. By adjusting the opening degree of the pressure adjustment valve 18, the outside air is taken into the vacuum drying container 4 from the outside air intake pipe 19, and the pressure inside the vacuum drying container 4 is adjusted to a predetermined pressure. The outside air taken into the outside air intake pipe 19 is preferably warm air so as not to reduce the drying efficiency.

  Here, the principle of vacuum drying will be described. Water boils at 100 ° C. under atmospheric pressure (1 atm), but if the air pressure is lowered, the boiling temperature also decreases. If it demonstrates with a specific example, in the graph which shows the water vapor pressure curve shown in FIG. 8, if it pressure-reducing from atmospheric pressure to 0.25 atmosphere, for example, a boiling temperature will be about 60 degreeC. An application of this principle to drying is called vacuum drying. The point to be noted in vacuum drying is that when water boils, it takes latent heat from the gas and lowers the temperature in the container, so it is necessary to supply warm heat to keep the temperature in the container constant. For this reason, it is desirable that the container body 4B is provided with heating means such as a heater.

  Assuming that the temperature of the vacuum drying container 4 is 65 ° C. and the vacuum reachability of the vacuum pump is 0.05 atm, in the graph shown in FIG. 8, 0.25 atm is sufficiently satisfied at the boiling condition of 60 ° C. Even if the temperature of the container 4 is allowed to remain at 65 ° C., it is sufficient to reduce the pressure in the vacuum drying container 4 to 0.25 atm. Thus, outside air can be taken into the vacuum drying container 4 by using a differential pressure of 0.2 atm. Thereby, by promoting the convection in the vacuum drying container 4, it is possible to eliminate the problem of the temperature drop in the container due to the release of latent heat caused by the boiling of the moisture content of the material W to be dried locally. At this time, the outside air taken into the vacuum drying container 4 from the outside air intake pipe 19 is preferably warm air so that the temperature in the vacuum drying container 4 does not decrease as described above.

  In addition, since the relative humidity of the air sucked into the rotary cylinder device 2 at the start of the drying operation of the material W to be dried stored in the vacuum drying container 4 is approximately 100%, There is a possibility that water droplets may be generated in the mode in which the air sucked from the vacuum drying container 4 is discharged.

  Specifically, a piston 52 is inserted into a cylinder 51 for a conventional vacuum pump shown in FIG. 8B. An annular seal cup 53 is overlaid on the piston head 52 a and is screwed and assembled by a seal cup presser 54. As shown in FIGS. 8A and 8B, a cylinder head portion 55 and a head cover 56 are assembled to the cylinder 51 so as to overlap each other. The cylinder head portion 55 and the head cover 56 are respectively formed with a suction flow path 57a for sucking air into the cylinder 51 and a discharge flow path 57b for discharging air from the cylinder 51. Pipe fittings 58a and 58b corresponding to the suction flow path 57a and the discharge flow path 57b are connected to the head cover 56, respectively. As shown in FIG. 8C, when air sucked into the cylinder 51 is discharged from the discharge passage 57 b through the reed valve 59 and the pipe joint 58 b, water droplets 60 generated in the cylinder 51 are discharged when the seal cup 53 is drained. May flow into the case body from the gap due to deformation due to water pressure. As a result, the life of the bearing 61 (see FIG. 7B) provided around the eccentric shaft around which the piston 52 rotates is extremely shortened.

  Therefore, as will be described later, the piston head portion 24b of the second double-headed piston set 24 that reciprocates in the evacuating cylinder 5 has an end surface of the piston head portion 24b in either the positive pressure or negative pressure direction. Seal cups 24c1 and 24c2 are provided to stand with respect to (pressure receiving surface). Thereby, it is possible to prevent water droplets generated in the cylinder that could not be realized by the seal cup 53 used in the conventional vacuum pump shown in FIG. 8 from flowing into the case body.

  Hereinafter, a schematic configuration of the rotary cylinder device 2 will be described with reference to an axial plan view of FIG. 4A, an exploded perspective view of FIG. 5, and FIGS. As shown in FIGS. 6A to 6C, in the case main body 3, the rotation of the drive shaft 2a that is rotationally driven by the motor M (see FIG. 1) is arranged orthogonal to the eccentric cam 22 in accordance with the inner cycloid principle. A piston unit P that converts into a reciprocating motion of a pair of double-headed piston sets 23, 24 (see FIG. 4A) is assembled so as to be relatively rotatable. The double-headed piston assembly refers to a single-headed piston unit in which a seal material such as a seal cup, a seal cup pressing member, and a piston ring is integrally assembled. This will be specifically described below.

In FIG. 5, a cylindrical eccentric cam 22 that can rotate relative to the first crankshaft 25 a, and a first double-headed piston set 23 and a second double-headed piston set 24 (piston unit P) with respect to the eccentric cam 22, respectively. It is assembled to allow relative rotation. Piston head portions 23b are formed at both ends in the longitudinal direction of the piston main body 23a of the first double-headed piston set 23, respectively. An annular seal cup 23c and a seal cup retainer 23d are superimposed on each piston head portion 23b, and are assembled together by screws 23e.
Piston head portions 24b are formed at both longitudinal ends of the piston main body 24a of the second double-headed piston set 24, respectively. Annular seal cups 24c1 and 24c2 and a seal cup retainer 24d are overlaid on each piston head portion 24b and assembled together by screws 24e.

  The first double-headed piston set 23 and the second double-headed piston set 24 are assembled to the outer periphery of the cylindrical body 22a of the eccentric cam 22 via bearings 26a and 26b, respectively. The first crankshaft 25a is fitted into the cylindrical hole of the eccentric cam 22 via a bearing, and the first balance weight 27a and the first drive shaft 2a1 and the second balance weight 27b and the second drive shaft 2a2 are attached to the end portions of both side shafts. Fit together. Then, the pins 28a and 28b are inserted through the first balance weight 27a and the second balance weight 27b, respectively, into the shaft end portion of the first crankshaft 25a to align them. In this state, the pin 28a and the fixing screw 29a are screwed together so as to be orthogonal to the first balance weight 27a, and the pin 28b and the fixing screw 29b are respectively assembled perpendicularly to the second balance weight 27b.

  The piston unit P is rotatably supported by fitting the first drive shaft 2a1 into the bearing 30a held by the first case body 3A and fitting the second drive shaft 2a2 into the bearing 30b held by the second case body 3B. Is done. In the present embodiment, the drive shaft 2a is divided into a first drive shaft 2a1 and a second drive shaft 2a2, and the first drive shaft 2a1 and the first balance weight 27a, and the second drive shaft 2a2 and the second balance weight 27b, respectively. It is assembled together.

  As shown in FIGS. 6A to 6C, a pair of evacuation cylinders 5 and a pair of pressure difference generation cylinders 6 are respectively inserted and assembled on opposite side surfaces of the case body 3. As shown in FIG. 5, the pressure difference generating cylinder 6 is overlaid with a cylinder head portion 32 via a seal material 31 and a head cover 34 via a seal material 33, and the case body 3 is opposed by a fixing screw 35. It is assembled on the side. Reed valves 32 a and 32 b for switching the flow of fluid into and from the flow path (suction and discharge) from each cylinder chamber are assembled to the cylinder head portion 32. A vacuum cover cylinder 5 is overlaid with a cylinder head portion 37 via a seal material 36 and a head cover 39 via a seal material 38, and assembled to the opposite side surface of the case body 3 by a fixing screw 40. Reed valves 37 a and 37 b for switching the flow of fluid into and from the flow path (suction and discharge) from each cylinder chamber are assembled to the cylinder head portion 37.

  As shown in FIG. 7A, a suction side reed valve 37a and a discharge side reed valve 37b are provided in the cylinder head portion 37 provided in the evacuation cylinder 5, respectively. The reed valve 37a on the suction side opens when the inside of the evacuation cylinder 5 becomes negative pressure and air is sucked in from the pipe joint 39a in the direction of the arrow. The discharge-side reed valve 37b is opened when the inside of the evacuating cylinder 5 becomes positive pressure and air is discharged from the pipe joint 39b in the direction of the arrow.

As shown in FIG. 7A, the suction-side reed valve 37a is assembled in a cantilevered manner with a screw 37c on the radially inner surface side of the cylinder head portion 37, and the discharge-side reed valve 37b is mounted on the radially outer surface side of the cylinder head portion 37. And cantilevered by screws 37d. Further, as shown in FIG. 7B, the head cover 39 is provided with screw holes 39c and 39d into which the pipe joints 39a and 39b are assembled by screwing.
The structure of the suction side reed valve 32a and the discharge side reed valve 32b provided in the cylinder head portion 32 provided in the pressure difference generating cylinder 6 and the structure of the head cover 34 are the same as those of the suction side reed valve 37a and the discharge side. This is the same as the reed valve 37b and the head cover 39 on the side.

  The first double-headed piston set 23 is inserted and assembled into the pressure difference generating cylinder 6 (see FIG. 5), and the second double-headed piston set 24 is inserted into the vacuuming cylinder 5 and assembled (see FIG. 6B). The first case body 3A and the second case body 3B are assembled by sandwiching the evacuation cylinder 5 and the pressure difference generation cylinder 6, and the fixing screws 21 are screws corresponding to the first case body 3A and the second case body 3B. The case main body 3 is integrally assembled by screwing into the holes (see FIG. 5).

  As shown in FIGS. 4B to 4D, piston head portions 24b are formed at both ends in the longitudinal direction of the piston main body 24a of the second double-headed piston set 24 that reciprocates in the evacuating cylinder 5. Seal cups 24c1 and 24c2 that stand up with respect to the end face of the piston head portion 24b are assembled to the piston head portion 24b so as to be stacked in any direction of positive pressure or negative pressure.

  4B to 4D, each of the seal cups 24c1 and 24c2 is formed in an annular shape, and a radial cross section in which the seal surface L1 and the seal surface L2 are orthogonal to each other is formed in an L shape. The seal cups 24c1 and 24c2 are overlapped with each other so that the seal surfaces L1 are parallel to each end surface (pressure receiving surface) of each piston head portion 24b, and the seal surfaces L2 stand up radially inward and radially outward. (See FIG. 6D). In this state, the seal cup holder 24d is overlaid and assembled integrally with the screw 24e (see FIG. 5). The seal cups 24c1 and 24c2 are formed by overlapping two parts, but may be formed integrally. As the seal cups 24c1 and 24c2, for example, a resin material such as a PEEK (polyetheretherketone) material having high slidability with a cylinder and high wear resistance is used.

  Thus, the seal cups 24c1 and 24c2 that stand up with respect to the end face of the piston head portion 24b in any direction of positive pressure or negative pressure in the piston head portion 24b that reciprocates in the evacuation cylinder 5. Therefore, it is possible to prevent water droplets generated in the cylinder, which could not be realized by the seal cup used in the conventional vacuum pump, from flowing into the case body 3. Further, the rotation of the drive shaft 2a (first drive shaft 2a1, second drive shaft 2a2) is converted into a reciprocating motion of a pair of double-headed piston sets 23, 24 arranged orthogonal to the eccentric cam 22 in accordance with the inner cycloid principle. By using at least one of the plurality of cylinders of the rotary cylinder device 2 as the evacuation cylinder 5 connected to the vacuum drying vessel 4, the pump device for evacuation can be reduced in size and the double-headed piston assembly Therefore, vibration and noise can be reduced with little mechanical loss caused by the reciprocating motion.

  Here, the first crankshaft 25a and the second crankshafts 25b, 25c (virtual shafts, centered on the drive shaft 2a (first drive shaft 2a1, second drive shaft 2a2) are formed on the eccentric cam 22. Referring to FIGS. 10A to 10D, an outline of the principle of the rotational motion of the pair of cylindrical bodies 22a) and the linear reciprocating motion (internal cycloid motion) of the first double-headed piston set 23 and the second double-headed piston set 24 will be described. explain. 10A to 10D show a state in which the first crankshaft 25a is rotated 90 ° around the center O (the first drive shaft 2a1 and the second drive shaft 2a2) counterclockwise by the rotation of the drive shaft 2a. It is shown schematically. When the first crankshaft 25a rotates around the center O (first drive shaft 2a1, second drive shaft 2a2) by the rotation of the drive shaft 2a, the second crankshaft 25b is on the diameter R1 of the rolling circle 43 of the virtual circle 42. The second crankshaft 25c reciprocates on the diameter R2 of the rolling circle 43.

  That is, the first crankshaft 25a and the eccentric cam 22 (FIG. 5) along the counterclockwise rotation track 44 having a radius r centering on the axis (center O) of the first drive shaft 2a1 and the second drive shaft 2a2. (See FIG. 6B, D) of the piston set connected to the eccentric cam 22 having the second crankshafts 25b, 25c as the axis. The reciprocating motion is repeated on the diameter R1 of the rolling circle 43 (concentric circle centered on the axis O) having a radius of 2r while rotating relatively, and the second double-headed piston set 24 moves the bearing 26b (see FIGS. 6B and D). Accordingly, the reciprocating motion is repeated on the diameter R2 of the rolling circle 43 having the radius 2r while relatively rotating. In an actual device, the eccentric cam 22 rotates relative to the first crankshaft 25a through bearings 25d and 25e (see FIG. 6B), and the first double-headed piston set 23 and the second double-headed piston set 24 are connected to the bearings 26a, Reciprocally move in the vacuuming cylinder 5 and the pressure difference generating cylinder 6 which are arranged orthogonally while being rotated relative to each other via 26b.

  The pressure difference generating cylinder 6 forms a positive pressure state or a negative pressure state by the reciprocating motion of the first double-headed piston set 23, creates a pressure difference inside and outside the case body 3, and the airflow flowing inside and outside the case body 3 Is preferably formed. As shown in FIG. 1, the air taken in from the intake pipe 12 is drawn into the pressure generating cylinder 6 through the pair of pipe joints 34a by the suction pipe 14 through the pair of pipe joints 13a. The air blown into the case body 3 from the pressure difference generating cylinder 6 through the connecting pipe 16, the pipe joint 15a, the connecting pipe 17 and the pipe joint 3a is exhausted from the inside of the case body 3 to the outside through the discharge hole 3b. .

  As a result, water droplets enter the case body 3 from the vacuum drying container 4 side through the seal cups 24c1 and 24c2 provided on the piston head portion 24b through slight irregularities present on the inner wall surface of the vacuuming cylinder 5. Even if it does, since the discharge hole 3b (refer FIG. 1, FIG. 3) provided in at least 1 place or several places is formed, a water | moisture content is evaporated by the airflow which flows inside and outside the case main body 3, and the case main body 3 It can be discharged to the outside.

  In the above embodiment, the air flow flowing inside and outside the case body 3 is formed by the pressure difference generating cylinder 6. For example, as shown by the arrow in FIG. 3, the pipe joint 3 c provided on the top surface portion of the case body 3. A suction pipe 41 may be provided, and hot air may be blown into the case main body 3 by a fan (not shown), or hot air compressed by a compressor (not shown) may be blown into the suction pipe 41. The warm air blown into the case main body 3 is exhausted from the discharge holes 3b provided at one or a plurality of locations on the top surface or the side surface of the case main body 3.

As shown in FIG. 6D, the cylinder head portion 37 is assembled so as to cover the cylinder opening 5b in which the cylinder chamber of the evacuating cylinder 5 is provided. The discharge port 37e provided in the cylinder head portion 37 is connected to the cylinder chamber and is provided so as to include the lower end edge in the gravity direction of the cylinder opening portion 5b. It should be noted that it is desirable that the horizontal pipe hole portion of the pipe joint 39b be similarly arranged.
As a result, even if water contained in the air sucked into the vacuuming cylinder 5 evacuated from the vacuum drying container 4 becomes water droplets and flows down to the lower edge in the gravity direction of the cylinder opening 5b of the vacuuming cylinder 5, it is discharged. It is possible to reliably discharge from the outlet 37e, and it is possible to minimize (reducing as much as possible) the remaining water in the vacuuming cylinder 5 from the water droplets.

  The vacuum drying container 4 shown in FIG. 1 is kept warm at a predetermined temperature, and the outside air taken into the container 4 is preferably warm air. As a result, water takes away latent heat when boiling, but if the vacuum drying container 4 is kept at a predetermined temperature, the temperature in the container 4 is prevented from lowering and the drying efficiency is not lowered. Further, if the outside air taken in to promote the convection of the air in the vacuum drying container 4 accompanying the suction of the vacuuming cylinder 5 is warm air, it prevents the condensation or the temperature in the container 4 from being lowered. be able to.

  As described above, when the vacuum drying apparatus 1 shown in the present embodiment is used, the drying time is shortened, the drying cost is reduced, the apparatus is downsized, the vibration noise during operation is reduced, and the rotary cylinder is reduced. The oil recovered from the apparatus 2 reduces the environmental load and can be used by ordinary households and small and medium-sized food business operators. The vacuum drying apparatus 1 disclosed in the present embodiment may be used, for example, for the purpose of drying and reducing food waste and food residues, but may also be used for generating dried foods that are dried by vacuum drying fruits and vegetables. For example, it is expected to be widely used as a vacuum drying apparatus 1 that can be used for home use or business use.

  In the above-described embodiment, the evacuation cylinder 5 and the pressure difference generation cylinder 6 are provided at positions opposed to the case body 3, but the present invention is not limited to this.

  DESCRIPTION OF SYMBOLS 1 Vacuum drying apparatus 2 Rotary cylinder apparatus 2a Drive shaft 2a1 1st drive shaft 2a2 2nd drive shaft 2b Drive pulley 3 Case main body 3A 1st case body 3B 2nd case body 3a, 3c, 4a, 4b, 13a, 15a, 34a, 34b, 39a, 39b Pipe joint 3b Discharge hole 4 Vacuum drying container 4A Lid 4B Container body W Dried object 5 Vacuum pulling cylinder 5b Cylinder opening 6 Pressure difference generating cylinder 7 Device base 7a Leg 8 Motor Shaft 8a Motor pulley 9 Timing belt 10, 14, 41 Suction pipe 11 Discharge pipe 12 Intake pipe 16, 17 Connecting pipe 18 Pressure adjustment valve 19 Outside air intake pipe 20 Pressure gauge 21, 29a, 29b, 35, 40 Fixing screw 22 Eccentric cam 22a Tube 23 First double-headed fixie Set 23a, 24a Piston body 23b, 24b Piston head portion 23c, 24c1, 24c2 Seal cup 23d, 24d Seal cup holder 23e, 24e Screw 24 Second double-headed piston set P Piston unit 25a First crankshaft 25b, 25c Second crankshaft 25d, 25e, 26a, 26b, 30a, 30b Bearing M Motor 27a First balance weight 27b Second balance weight 28a, 28b Pin 31, 33, 36, 38 Seal material 32, 37 Cylinder head portion 32a, 32b, 37a, 37b Reed valve 37c, 37d Screw 37e Discharge port 34, 39 Head cover 42 Virtual circle 43 Rolling circle 44 Rotating orbit

Claims (4)

A case main body containing a rotary cylinder device that converts rotation of a drive shaft that is rotationally driven by a drive source into a reciprocating motion of a pair of double-headed piston sets arranged orthogonal to an eccentric cam in accordance with the principle of inner cycloid A vacuum drying apparatus in which a vacuum drying container in which a dried product is stored is connected to a pipe,
At least one cylinder among a plurality of cylinders provided in the case body into which the pair of double-headed piston sets are slidably inserted is connected to the vacuum drying container in which an object to be dried is stored and vacuumed. The remaining cylinders are used as pressure difference generating cylinders that generate a pressure difference between the inside and outside of the case body to form an air flow flowing inside and outside the case body, and reciprocate within the vacuuming cylinder. A vacuum drying apparatus, wherein the piston head portion is provided with a seal cup that stands up with respect to an end surface of the piston head portion in any direction of positive pressure or negative pressure.   The pressure difference generating cylinder forms a positive pressure state or a negative pressure state by reciprocating movement of the double-headed piston set, creates a pressure difference inside and outside the case body, and forms an airflow flowing inside and outside the case body. Item 2. A vacuum drying apparatus according to Item 1.   The vacuum drying apparatus according to claim 1, wherein the discharge port connected to the cylinder chamber of the vacuuming cylinder is provided so as to include a lower end edge in a gravitational direction of the cylinder opening.   The vacuum drying apparatus according to any one of claims 1 to 3, wherein the vacuum drying container is kept warm at a predetermined temperature, and the outside air taken into the container is warm air.