JP5982181B2 - Cremation furnace - Google Patents

Description

  The present invention relates to a cremation furnace that efficiently cremates an object.

  A cradle formed in the longitudinal direction of an animal or a human corpse (object) accommodated in a cremation room is provided directly below the object, and a burner that emits a flame toward the object is provided. A cremation furnace disposed near one end in the longitudinal direction is conventionally known.

  In the cremation furnace of this configuration, during the cremation, the unburned matter that is the separated product during combustion of the target object is supported on the upper surface side of the cradle as well as the burned product that is the separated product after burning the target object. Unburned material on the cradle is also gradually cremated by the flame emitted from the burner.

  As an improvement of such a cremation furnace, a control unit for controlling the posture of the burner is provided, and by changing the posture of the burner appropriately, unburned matter on the cradle is efficiently cremation is shown in Patent Document 1 Cremation furnaces are known.

JP 2003-322316 A

  However, in the cremation furnace of the above document, the burner is arranged near one end in the longitudinal direction of the cradle, and even when the posture of the burner is appropriately controlled to improve the cremation efficiency, the side away from the burner on the cradle However, there is a problem that unburned materials tend to be biased and cremation takes time.

  The present invention includes a cradle that is positioned directly below the object and formed in the longitudinal direction of the object, and a burner that radiates flame to the object is disposed near one end of the cradle in the longitudinal direction. An object is to provide a cremation furnace capable of efficiently cremation of unburned material on a table.

The cremation furnace of the present invention is provided with a cradle formed in the longitudinal direction of a target object housed in a cremation chamber, directly below the target object, and a burner that emits a flame toward the target object side. A cremation furnace disposed near one end in the longitudinal direction of the slab, provided with a tilting actuator for tilting and driving the cradle so that the cradle tilts upward in a direction away from the burner , and a vibration actuator for vibrating the cradle Provided in the recess for receiving the object cremated on the upper surface side of the cradle or the object being cremated, and the recess has a plurality of guide grooves extending in the longitudinal direction of the cradle in the width direction of the cradle. It is formed in a parallel state, and is characterized in that a flat combustion surface is formed at a location closer to the burner than the guide groove in the recess .

  With the above configuration, the cradle can be tilted by the tilting actuator, and the unburned material can be slid down to the burner side by the tilted cradle upper surface. It becomes possible to carry out efficiently.

  In addition, you may form the inclined surface which inclined downward toward the bottom face side of this recessed part on the edge side of the said recessed part.

  Further, a cooling means for cooling the tilting actuator or the vibration actuator may be provided.

  The cooling means may be formed by forming a flow path for supplying cooling air to the tilting actuator or the vibration actuator, and the flow path may communicate with the cremation chamber.

  On the other hand, a control unit that controls the tilt of the cradle with the tilting actuator is provided, and the control unit holds the cradle horizontally or substantially horizontally before performing the tilting process of tilting the cradle with the tilting actuator. Cremation may be performed.

  The control unit may be configured to control the vibration of the cradle with the vibration actuator, and the control unit may vibrate the cradle with the vibration actuator during the tilt process.

In addition, the control unit is configured to control the vibration of the cradle with the vibration actuator, and the control unit may vibrate the cradle with the vibration actuator after the horizontal processing and before the tilt processing. Good.
Moreover, the cremation furnace of the present invention is provided with a cradle formed in the longitudinal direction of the target object accommodated in the cremation room, directly below the target object, and a burner that radiates flame toward the target object side, A cremation furnace disposed near one end in the longitudinal direction of the cradle, provided with a tilting actuator for tilting the cradle so that the cradle tilts upward in a direction away from the burner, and for vibrating the cradle An actuator is provided, and a control unit is provided for controlling the tilt of the cradle with the tilting actuator and controlling the vibration of the cradle with the vibration actuator. The control unit performs a tilting process for tilting the cradle with the tilting actuator. In addition, a horizontal process is performed in which the cradle is held horizontally or substantially horizontally and cremation is performed, and the cradle is vibrated by a vibration actuator after the horizontal process and before the tilting process. It is characterized in.
Further, a cooling means for cooling the tilting actuator or the vibration actuator may be provided.

  Note that weight detection means for detecting the weight of the target object may be provided, and the control unit may set the processing time depending on the weight of the target object detected by the weight detection means.

  According to the present invention, it is possible to incline the cradle by the tilt driving means, and to allow the unburned material to slide down to the burner side by the tilted cradle upper surface. Can be done automatically.

It is side sectional drawing which shows the structure of the cremation furnace to which this invention is applied. It is a front sectional view showing the configuration of a cremation furnace to which the present invention is applied. (A) is a plan view of the cradle, (B) is a BB cross-sectional view of (A), and (C) is a CC cross-sectional view of (A). It is a block diagram of a control part. It is a processing flow figure of standby processing and horizontal processing which a control part performs. It is a processing flow figure of the vibration processing which a control part performs. It is a processing flowchart of the inclination process which a control part performs. It is a processing flow figure showing other examples of standby processing and horizontal processing. It is a processing flow figure showing other examples of vibration processing. It is a process flow figure of other examples of inclination processing. It is a processing flow figure showing other examples of processing which a control part performs. It is a sectional side view of the cremation furnace which shows the structure of another embodiment of this invention. It is a front sectional view of a cremation furnace which shows the composition of another embodiment of the present invention. (A) thru | or (C) are the planar views, side views, and front sectional views of the cradle shown in FIGS.

  1 and 2 are a side sectional view and a front sectional view showing the structure of a cremation furnace to which the present invention is applied. The cremation furnace 1 is composed of a refractory material such as brick or ceramic, and the main part of the cremation furnace 1 such as a roof, a peripheral wall, and a floor is composed of concrete and the like. Alternatively, a main combustion chamber (cremation chamber) 2 in which a corpse (object) such as an animal is accommodated and cremation is formed, and a recombustion chamber 3 is formed immediately above the main combustion chamber 2 in the cremation furnace 1. The combustion chamber 2 and the recombustion chamber 3 communicate with each other through a flue 4.

  A burner 6 for main combustion is installed on the back side of the main combustion chamber 2, while an accommodation port 2 a is formed on the front side of the main combustion chamber 2, and this accommodation port 2 a is opened and closed by a fire door 7. In addition, the wooden basket 8 in which the object such as a corpse is stored is taken in and out through the storage port 2a. The main combustion chamber 2 is a rectangular parallelepiped space in which the direction from the front to the back side or from the back side to the front is the longitudinal direction (front-rear direction), and the soot 8 is accommodated along this longitudinal direction.

  Specifically, the soot 8 is positioned and placed on a carriage-type receiving base 9 extending in the longitudinal direction of the main combustion chamber 2, whereby the receiving base 9 is positioned directly below the soot 8 (target object), The cradle 9 is configured to be driven to tilt by a pair of left and right tilt cylinders (tilting actuators) 11 and to be driven to vibrate by a vibration cylinder (vibration actuator) 12.

  The burner 6 is disposed at a position slightly separated from the longitudinal end (flame side end 9a) of the cradle 9 along the longitudinal direction, and the flame radiation direction of the burner 6 is the flange 8 in which the object is placed. And the cradle 9 side. In other words, the burner 6 is disposed near the flame side end 9 a of the cradle 9. Specifically, the burner 6 can be swung by the movable mechanism 13 in a state where the front end side of the burner 6 is inserted into the main combustion chamber 2 through an installation hole 1 a formed in the back side of the main combustion chamber 2. It is supported by.

  The movable mechanism 13 changes the posture of the burner 6 to adjust the flame injection direction. In addition, an inclined surface 14 is formed between the installation hole 1 a in the main combustion chamber 2 and the cradle 9 and is inclined downward in the flame emission direction of the burner 6.

  3A is a plan view of the cradle, FIG. 3B is a cross-sectional view taken along line BB in FIG. 3A, and FIG. 3C is a cross-sectional view taken along line CC in FIG. The cradle 9 is composed of a refractory metal such as stainless steel and is formed in a rectangular frame shape, and a rectangular plate-like shape that is fixed in a fitted state in the frame body 16 in the front-rear direction. A tray 17, a pair of left and right mounting frames 18, 18 fixed to the lower surface side of the frame body 16, and left and right mounting frames 18, 18 supported by the left and right mounting frames 18, 18 so as to be rotatable around a shaft. Directional axles 21 and the wheels 22 respectively installed at the left and right ends of the axles 21.

  The pair of left and right mounting frames 18 and 18 are channel-shaped members having a U-shaped cross-sectional shape with the left and right outer sides open, and extending in the front-rear direction. An axle 21 having wheels 22 and 22 on both right and left ends is provided. A plurality of them are arranged in parallel in the front-rear direction.

  On the other hand, as shown in FIGS. 1 to 3, a pair of left and right guide rails 23, 23 are fixed on the floor 2 b of the main combustion chamber 2, and a pair of left and right wheels 22 are attached to the left and right guide rails 23, 23. , 22 are supported by the left and right guide rails 23, 23 so as to be slidable back and forth.

  By this back-and-forth slide, it becomes possible to easily take in and out the cradle 9 from the main combustion chamber 2 through the storage port 2a, and the main cremation furnace 1 becomes a cart type cremation furnace. Further, a stopper portion 23 a is formed at the end of the guide rail 23 on the burner 6 side so as to restrict the cradle 9 from sliding from the predetermined position where the entirety of the guide rail 9 is accommodated in the main combustion chamber 2 to the far side. ing.

  The saucer 17 is a bone saucer made of a heat-resistant member such as a brick, and is separated from a target object (burned matter) that has been burned into a plurality of bones, etc. The unburned material is received on the upper surface of the tray 14. A recess 24 that is recessed downward is formed on the upper surface of the tray 17.

  An inclined surface 24b that is inclined downward toward the bottom surface 24a on the center side of the recess 24 is formed on each of the front and rear ends and the left and right ends of the recess 24. In addition, the bottom surface 24a of the recess 24 has a longitudinal direction of the tray 17 A plurality of belt-shaped convex portions 26 extending upward and projecting upward are integrally formed, and a plurality of the convex portions 26 are arranged in parallel at predetermined intervals in the width direction of the tray 17, and adjacent to the adjacent convex portions 26. Guide grooves 27 are formed between the convex portions 26 and the inclined surfaces 26b, respectively.

  Further, each of the convex portions 26 is not formed from one end to the other end in the longitudinal direction of the concave portion 24, and the convex portion 26 is not provided on the portion closer to the burner 6 of the concave portion 24. A flat combustion surface 28 is formed. The combustion surface 28 is formed on the bottom surface 24 a together with the bottom surface of each guide groove 27.

  The reburning chamber 3 is provided with a reburning burner (not shown), and the introduced material introduced into the reburning chamber 3 from the flue 4 is burned by a flame radiated from the burner. By the way, the exhaust gas generated when the object is burned and cremated becomes the above-mentioned introduction, and the exhaust gas is completely burned in the recombustion chamber 3, thereby suppressing the generation of odors and harmful substances. .

  In the cremation furnace 1 configured as described above, a flame is radiated from the main combustion burner 6 in the main combustion chamber 2 in which the combustible flame 8 containing the subject is accommodated, and the subject becomes the flame 8. With cremation.

  In addition, in order to efficiently cremate a part of the object far from the burner 6, the cremation furnace 1 is provided with the above-described tilt cylinder 11 and vibration cylinder 12, which are a control unit configured by a microcomputer or the like. The drive is controlled by 29 (see FIG. 4).

  Next, based on FIG.1 and FIG.2, the structure of the inclination cylinder 11 and the vibration cylinder 12 is demonstrated.

  The tilt cylinder 11 and the vibration cylinder 12 include cylindrical cylinder bodies 11a and 12a and pistons 11b and 12b that reciprocate on the inner peripheral sides of the cylinder bodies 11a and 12a, respectively. The tilt cylinder 11 may be a hydraulic cylinder, an air cylinder, or an electric cylinder as long as it moves directly. On the other hand, the vibration cylinder 12 may be anything as long as vibration can be applied to the cradle 9. For example, an air vibration cylinder that directly vibrates by expansion and contraction, or a normal cylinder provided with a vibration motor. A straight-acting electric cylinder or the like may be used.

  The inclined cylinders 11 and 11 are respectively disposed at left and right symmetrical positions in front of the lower surface of the cradle 9 accommodated on the farthest side, and the vibration cylinder 12 is located far from the burner 6 on the lower surface side of the cradle 9. In addition, one is provided at the left and right central portion on the back side of the inclined cylinder 11.

  Explaining the specific installation state, on the cremation furnace 1 side, the installation space 31 consisting of holes or holes opened upward is the same number as the cylinders 11 and 12 (specifically, three). Drilled in the range from the floor surface 2b to the floor, the cylinder bodies 11a, 12a of the cylinders 11, 12 are individually fixed in the plurality of installation spaces 31 with the pistons 11b, 12b of each cylinder being fixed. The front end portion can protrude upward from the floor surface 2 b of the main combustion chamber 2 through the installation space 31.

  Abutting bodies 32 and 33 that abut on the lower surface of the cradle 9 are integrally formed at the tip portions of the pistons 11b and 12b, while a contact portion between the pistons 11b and 12b of the cradle 9 is in contact. This plate 34, 36 is provided, the tip of the piston 11b, 12b of the cylinder 11, 12 is a free end, the contact plate 34, 36 and the contact body 32, 33 are in a disconnected state, contact To do.

  When the left and right tilt cylinders 11 are both extended, the tip side of the tilt cylinder 11 comes into contact with the contact plate 34, and the contact plate 34 is pushed upward, so that the stopper portion 23a side portion of the cradle 9 (the innermost part) The cradle 9 is swung upward with the side wheel 22) as a fulcrum, and the upper surface of the cradle 9 is inclined downward toward the burner 6 side. That is, the cradle 9 is configured to be switchable between a horizontal horizontal posture with the floor surface 2b of the main combustion chamber 2 and an inclined posture inclined upward toward the side away from the burner 6 by the extension operation of the inclined cylinder 11. Has been.

  At the stage where the cremation has progressed to some extent, as described above, the cradle 9 is inclined downward toward the burner 6 to bring the unburned object of the object into the combustion surface 28 side and perform efficient cremation. In this case, the flame radiation direction of the burner 6 may be adjusted via the movable mechanism 13 so that the object is efficiently burned in accordance with the inclination of the cradle 9.

  At this time, the plurality of guide grooves 27 can more smoothly guide the unburned material being cremated to the inclined surface 28 side. Furthermore, it becomes possible to efficiently bring the unburned material on the edge side toward the center side of the recess 24 by the four inclined surfaces 24b surrounding the bottom surface 24a.

  Incidentally, in actuality, in addition to the unburned matter of the target object, the already burned combusted matter is appropriately brought to the above location, and the plurality of guide grooves 27 are formed by the exhaust gas generated when the target object is burned. The function of smoothly guiding the gas upward is also exhibited, whereby the exhaust gas is smoothly introduced into the recombustion chamber 3 from the flue 4.

  The vibration cylinder 12 vibrates the cradle 9, and by this vibration and the four inclined surfaces 24 b surrounding the bottom surface 24 a, the unburned material on the edge side can be more efficiently brought to the center side of the recess 24. become. In addition, this vibration makes it possible to efficiently slide off unburned matter and burned matter on the pedestal 9 in the inclined posture.

  At this time, the cradle 9 is stably supported by the stopper portion 23 a and the left and right inclined cylinders 11, and the three-point supported stopper portion 23 a and the central portions of the left and right inclined cylinders 11 and 11 are vibrated. Therefore, the balance of the cradle 9 is also maintained in a good state. Incidentally, the vibration cylinder 12 is configured to be able to apply vibration to the receiving allowance 9 of any inclination angle.

  These actuators 11 and 12 are heated by the heat in the main combustion chamber 2 during the cremation, and there is a risk of the temperature rising and causing a failure. To prevent such a failure, the cylinders 11 and 12 are installed. Cooling means for cooling is provided in the illustrated cremation furnace 1.

  Specifically, the cooling means includes a flow path 37 that supplies cooling air to each installation space 31, and cooling air is supplied from the flow path 37 by a supply device (not shown) such as a compressor. It is supplied into the installation space 31. Since the flow path 37 communicates with the main combustion chamber 2 via the installation space 31, the air supplied from the flow path 37 to the actuators 11 and 12 is supplied from the upper side of the installation space 31 to the main combustion chamber. 2 is used as combustion air. Thus, since the supplied air is used for both cooling and combustion, the configuration is simplified.

  Next, the configuration of the control unit 29 will be described with reference to FIGS.

  FIG. 4 is a block diagram of the control unit. The input side of the control unit 29 includes a temperature sensor 38 which is a temperature detecting means for detecting the temperature of the main combustion chamber 2, the recombustion chamber 3, the soot 8 in the main combustion chamber 2 or the object in the main combustion chamber 2, and a receiver. An inclination angle potentiometer 39 which is an inclination detection means for detecting the inclination angle of the base 9 and a load sensor 41 which is a weight detection means for detecting a load acting on the upper surface side of the receiving base 9 including a partial deviation. And are connected.

  On the other hand, the tilt cylinder 11, the vibration cylinder 12, and the movable mechanism 13 described above are connected to the output side of the control unit 29. That is, the control unit 9 is configured to perform vibration control and tilt control of the cradle 9 and to control the flame emission direction of the burner 6.

  And this control part 29 waits for the start of cremation standby processing A, and horizontal processing B which holds cradle 9 in a horizontal posture during horizontal processing time T1, which is a predetermined time after the start of cremation, During the vibration processing time T2, which is a predetermined time after the horizontal processing, the vibration processing C for vibrating the pedestal 9 in the horizontal posture by the vibration cylinder 11, and the inclination processing which is a predetermined predetermined time after the vibration processing At time T3, the tilt cylinder 11 is configured to perform tilt processing D for switching the cradle 9 to the tilted posture.

  FIG. 5 is a processing flow diagram of standby processing and horizontal processing performed by the control unit, FIG. 6 is a processing flow diagram of vibration processing performed by the control unit, and FIG. 7 is a processing flow of tilt processing performed by the control unit. FIG. When the power is turned on, the control unit 29 starts processing from step S1. Incidentally, when the processing is started, the cradle 9 is held in a horizontal posture.

  In step S1, various temperatures are detected by the temperature sensor 41. If the temperature has risen to a temperature at which cremation has been started, the process proceeds to step S2, and if it has not risen to such a temperature, step S1 is executed again. In step S2, it is detected by the load sensor 41 whether or not the object (the bag 8 containing the object) is placed on the cradle 9, and if it is detected that the object is placed, The process proceeds to step S3, and if not detected, the process returns to step S1.

  In step 3, it is determined that the cremation has started, the weight of the object or the weight of the object and the rod 8 is detected from the load sensor 41, and according to the detected weight, the horizontal processing time T1 described above, The vibration processing time T2 and the inclination processing time T3 are set, and the process proceeds to step S4.

  The processes in steps S1 to S3 described above constitute the standby process A described above. Further, the horizontal processing time T1, the vibration processing time T2, and the tilt processing time T3 are appropriately set according to the weight of the object. For example, if the body is obese, the weight is heavy and processing takes time, so the horizontal processing time T1, the vibration processing time T2, and the tilt processing time T3 are set longer, and if the body is thin, the weight However, the horizontal processing time T1, the vibration processing time T2, and the tilt processing time T3 may be set shorter.

  In step S4, after resetting the timer built in the control unit 29, the counting is started, and the process proceeds to step S5. In step S5, the temperature sensor 38 is used to confirm that the cremation is in progress. If the temperature is during the cremation, the process proceeds to step S6, but the cremation has been stopped or terminated for some reason. If so, the entire process is terminated.

  In step S6, based on the detection value from the load sensor 41, the progress degree of combustion of the object in the horizontal process B stage is estimated. If the combustion has progressed by a predetermined amount or more, the horizontal process B is terminated and the vibration process is performed. The process proceeds to step S9 constituting a part of C, and if the combustion does not proceed more than a predetermined amount, the process proceeds to step S7.

  In step S7, based on the detection value from the load sensor 41, it is determined at which position of the cradle 9 the combustion is not progressing, and the posture of the burner 6 is set so that the flame is emitted toward that position. Is controlled by the movable mechanism 13, and the process proceeds to step S8.

  In step S8, it is checked whether or not the timer count has passed the horizontal processing time T1 set as described above. If not, the process returns to step S5, while If so, the process proceeds to step S9.

  The processing in steps S4 to S8 is horizontal processing B, and the horizontal processing B is basically continued during the horizontal processing time T1 by the processing in step S8, but the change in the weight of the object is performed. Therefore, if the combustion proceeds more than expected, the process proceeds to the vibration process C after step S9.

  In step S9, after resetting the timer, counting is started, and the process proceeds to step S10. In step S10, as in step S5, the temperature sensor 38 is used to confirm that the cremation is being performed. If the temperature is during the cremation, the process proceeds to step S11, but the cremation has been stopped or terminated for some reason. If the temperature has dropped, the entire process is terminated.

  In step S11, based on the detection value from the load sensor 41, the degree of progress of combustion of the target object in the vibration processing C stage is estimated, and if the combustion proceeds more than expected, a part of the tilt processing D is configured. On the other hand, if not proceeding to step S14, the process proceeds to step S12.

  In step S12, based on the detection value from the load sensor 41, it is determined at which position of the cradle 9 the combustion is not progressing, and the posture of the burner 6 is set so that the flame is emitted toward that position. Is controlled by the movable mechanism 13, and the horizontal position of the cradle 9 is driven to vibrate by the vibration cylinder 12, and the process proceeds to step S 13.

  In step S13, it is checked whether the count of the timer has passed the vibration processing time T2 set as described above. If not, the process returns to step S10, while If so, the process proceeds to step S14.

  The processing from step S9 to step S13 becomes the vibration processing C, and the vibration processing C is basically continued during the vibration processing time T2 by the processing in step S13, but the change in the weight of the object is performed. If it is confirmed that the combustion is proceeding more than expected, the process proceeds to the inclination process D after step S14.

  In step S14, after resetting the timer, counting is started, and the process proceeds to step S15. In step S15, as in steps S5 and S10, the temperature sensor 38 is used to confirm that the cremation is in progress. If the temperature is during cremation, the process proceeds to step S16, but the cremation is canceled or terminated for some reason. If the temperature is lowered, the entire process is terminated.

  In step S16, based on the detected value from the load sensor 41, the degree of progress of combustion of the target object in the vibration processing D stage is estimated, and if the combustion is proceeding more than expected, the entire process is terminated. If not, the process proceeds to step S17.

  In step S17, based on the detection value from the load sensor 41, it is determined at which position of the cradle 9 the combustion is not progressing, and the posture of the burner 6 is set so that the flame is emitted toward that position. Is controlled by the movable mechanism 13, and the cradle 9 is switched to the tilted posture by the tilt cylinder 11, and the process proceeds to step S18.

  By the way, the inclination degree is detected by the load sensor 41 with the bias of the object located on the cradle 9, and the location where the unburned matter is concentrated is estimated from the bias degree. The degree of inclination of the cradle 9 for guiding to the combustion surface 28 may be determined. In such control, in some cases, there is a case where there is almost no inclination and the cradle 9 is substantially horizontal.

  In addition, the cradle 9 switched to the inclined posture may be vibrated by the vibration cylinder 12. Further, the posture control of the burner 9 via the movable mechanism 13 is performed based on the detection result detected by the tilt angle potentiometer 39 so that the flame emission direction is optimally set according to the tilt angle of the cradle 9. May be performed.

  In step S18, it is checked whether or not the count of the timer has passed the tilt processing time T3 set as described above. If not, the process returns to step S15 while the elapsed time. If so, the entire process is terminated.

  The processes of Step S14 to Step S18 become the inclination process D, and the inclination process D is continued in principle during the period of the inclination process time T3 by the process of Step S18, but the change in the weight of the object is performed. If it is confirmed that the combustion has progressed more than expected and the cremation has been completed, the entire process is terminated at that point.

  According to the cremation furnace 1 configured as described above, after a predetermined time has elapsed since the start of the cremation, the vibration process C is executed, the cradle 9 vibrates, and the unburned object and the burned object of the target object are inclined surfaces 24b. As a result, the recess 24 is efficiently moved toward the bottom surface 24a. Subsequently, an inclination process D is performed, and unburned matter and burned matter brought to the center side of the recess 24 are guided by the burner 6 so as to slide down to the combustion surface 28 side where it can be burned efficiently. Efficient cremation of the burning material is performed.

  In addition, since the horizontal processing B is performed before the vibration processing C and the tilt processing D, the combustion of the target object proceeds to some extent, and the unburned material and the combustion product of the target object exist on the cradle 8. In the state, the vibration process C and the tilt process D are performed.

  The tilting actuator 11 is not limited to a cylinder, and may be one that lifts the end of the cradle 9 opposite to the flame side end 9a. A link mechanism that lifts or lifts the opposite end may be used.

  In addition, the vibration actuator 12 may also be used as the tilt actuator 11 if vibration is applied to the cradle 9, and drive the tilt actuator 11 frequently to apply vibration to the cradle 9. Incidentally, if vibration is not applied to the cradle 8 in the tilted posture, the vibration actuator 12 may be configured using a cradle 8 in the tilted posture that cannot be vibrated.

  Further, while the tilt process D is being performed, the pedestal 9 in the tilted posture may be vibrated by the vibration cylinder 11 as described above. In this case, during the tilt process time T3, in all time zones. The cradle 9 may be vibrated by the vibration cylinder 11, or the cradle 9 may be vibrated by the vibration cylinder 11 only in the latter half or the final stage of the tilt processing time T 3, or the load sensor 41 is detected. Based on the result, the cradle 9 may be vibrated when necessary.

  Next, with reference to FIG. 8 to FIG. 11, differences from the above-described example will be described regarding another example of the processing content performed by the control unit 29.

  FIG. 8 is a process flow diagram illustrating another example of the standby process and the horizontal process, FIG. 9 is a process flowchart illustrating another example of the vibration process, and FIG. 10 is a process flowchart illustrating another example of the tilt process. It is. In the standby process A, the horizontal process B, the vibration process C, and the tilt process D, the detection of the weight of the object located on the cradle 9 and its burned and unburned products may be omitted.

  Specifically, in the standby process A, in step S1, various temperature detections are performed by the temperature sensor 41. If the temperature has increased to the temperature at which cremation has been started, the process proceeds to step S3. In the horizontal process B, the temperature sensor 38 is used to confirm that the cremation is being performed in step S5. If the temperature is during the cremation, the process proceeds to step S7. In the vibration process C, in step S10, the temperature sensor 38 is used to confirm that the cremation is being performed. If the temperature is being cremation, the process proceeds to step S12. Furthermore, in the vibration process D, it is confirmed in step S15 that the temperature sensor 38 is used for cremation, and if it is the temperature during cremation, the process proceeds to step S17.

  FIG. 11 is a process flow diagram illustrating another example of the process performed by the control unit. As shown in the figure, in the above-described example, the standby process A → horizontal process B → vibration process C → tilt process D proceeds, but the vibration process C is omitted and the standby process A → horizontal process B → tilt process. You may proceed with D.

  Next, based on FIG. 12 thru | or FIG. 14, a different point from the above-mentioned form is demonstrated about another embodiment of this invention.

  12 and 13 are a side sectional view and a front sectional view of a cremation furnace showing a configuration of another embodiment of the present invention, and FIGS. 14A to 14C are cradles shown in FIGS. They are a top view, a side view, and a front sectional view. The cremation furnace 1 shown in the figure is a Rostor-type cremation furnace, and since the cradle 9 is not a carriage, the carriage 1 has a frame 16 and a tray 17, while the wheel 22 and the wheel 22 are attached to each other. The mounting frame 18, the bearing portion 19, and the axle 21 which are members for fixing to the frame body 16 are omitted.

  The cradle 9 is placed directly on the floor 2b of the main combustion chamber 2 so as to be slidable in the longitudinal direction of the cradle 9. In the above-described example, the stopper portion is integrally formed with the rear end portions of the guide rails 23 and 23. 23a is an independent member fixed to the back side of the floor 2b of the main combustion chamber 2. The stopper 23a abuts against the end of the frame 16 of the cradle 9 and receives further on the back side. The base 9 does not slide, and this abutting portion serves as a vertical swing fulcrum of the base 9 when the tilt cylinder 11 is expanded and contracted.

  Further, a left and right protruding portion 42 that protrudes upward in the thickness direction is formed at the front side end portion of the frame body 16, and a U-shape in a plan view is formed at the central portion in the left and right direction on the front side surface of the protruding portion 42. A grip portion 43 is formed. By gripping this gripping portion 43, the receiving base 9 can be easily put in and out of the storage port 2a.

  A horizontal rooster 44 is installed between the cradle 9 and the rod 8 positioned immediately above the rod 8 and the object housed in the rod 8. The rooster 44 is used to burn the burning object. It is formed in the shape of a mesh or a lattice so that objects and unburned materials can pass through and leak, and the soot 8 can be placed directly on the upper surface of the rooster 44 or by the inner wall of the main combustion chamber 2 It mounts on the formed horizontal mounting surfaces 46 and 46.

  In addition, in the control of the tilt cylinder 11 and the vibration cylinder 12 during the cremation, since the bag is not placed directly on the cradle 9, without applying a downward load acting on the upper surface of the cradle 9, Since it is necessary to determine the start of cremation or the like, the processes shown in FIGS. 8 to 11 are performed. By the way, means for detecting the bias of the load acting on the upper surface of the cradle 9 by the load sensor 41 and controlling the flame radiation direction of the burner 6 is such that the burned or unburned material of the cremation body is on the cradle 9. Since it falls sequentially, this cremation furnace 1 is also effective.

  According to the cremation furnace 1 configured as described above, the combustion proceeds from the lower surface side of the casket 8, so that efficient cremation can be performed.

1 Cremation furnace 2 Main combustion chamber (cremation chamber)
9 Receiving base 6 Burner 11 Inclination cylinder (Inclination actuator, Actuator)
12 Vibrating cylinder (vibration actuator, actuator)
24 concave portion 24a bottom surface 24b inclined surface 27 guide groove 28 combustion surface 29 control unit 37 flow path 41 load sensor (weight detection means)

Claims (11)

A cradle formed in the longitudinal direction of the object accommodated in the cremation room is provided directly below the object,
A cremation furnace in which a burner that emits a flame toward the object side is disposed near one end in the longitudinal direction of the cradle,
A tilting actuator is provided to drive the cradle so that the cradle tilts upward in a direction away from the burner ;
Provide a vibration actuator to vibrate the cradle,
Form in the recess to receive the object cremated on the upper surface side of the cradle or the object being cremated,
In the recess, a plurality of guide grooves extending in the longitudinal direction of the cradle are formed in a parallel state in the width direction of the cradle,
A cremation furnace characterized in that a flat combustion surface is formed at a location closer to the burner than the guide groove in the recess . The cremation furnace according to claim 1 , wherein an inclined surface that is inclined downward toward the bottom surface side of the concave portion is formed on an edge side of the concave portion. Cremation furnace according cooling means to claim 1 or 2 provided for cooling the tilt actuator or vibration actuator. The cooling means is configured by forming a flow path for supplying cooling air to the tilting actuator or the vibration actuator,
The cremation furnace according to claim 3 , wherein the flow path communicates with the cremation chamber. A control unit for controlling the inclination of the cradle by an inclination actuator;
The control unit, before performing the tilting process to tilt the cradle by tilting actuator, according to any one of claims 1 to perform the horizontal processing for cremation holds the cradle in the horizontal or substantially horizontal 4 Cremation furnace. Configure the control unit to control the vibration of the cradle with the vibration actuator,
The cremation furnace according to claim 5 , wherein the controller vibrates the cradle with a vibration actuator during the tilting process. Configure the control unit to control the vibration of the cradle with the vibration actuator,
The cremation furnace according to claim 5 , wherein the control unit vibrates the cradle with a vibration actuator after the horizontal processing and before the tilting processing. A weight detection means for detecting the weight of the object is provided,
The cremation furnace according to any one of claims 5 to 7 , wherein the control unit sets the processing time according to the weight of the object detected by the weight detection means.   A cradle formed in the longitudinal direction of the object accommodated in the cremation room is provided directly below the object,
  A cremation furnace in which a burner that emits a flame toward the object side is disposed near one end in the longitudinal direction of the cradle,
  A tilting actuator is provided to drive the cradle so that the cradle tilts upward in a direction away from the burner;
  Provide a vibration actuator to vibrate the cradle,
  A control unit that controls the tilt of the cradle with the tilt actuator and controls the vibration of the cradle with the vibration actuator,
  The controller performs a horizontal process of performing cremation by holding the cradle horizontally or substantially horizontally before performing the tilt process of tilting the cradle by the tilt actuator, and after the horizontal process and the tilt process. Before starting, vibrate the cradle with the vibration actuator
  A cremation furnace characterized by that.   Cooling means for cooling the actuator for tilting or the actuator for vibration is provided.
  The cremation furnace according to claim 9.   A weight detection means for detecting the weight of the object is provided,
  The control unit sets the processing time according to the weight of the object detected by the weight detection means.
  The cremation furnace according to claim 9 or 10.

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