JP5146374B2 - Toilet equipment - Google Patents

Description

  The present invention relates to a general toilet apparatus installed in a home or public facility, a portable toilet apparatus that can be simply installed and used outdoors or used for in-vehicle use, and a nursing toilet apparatus. It is about.

  Conventionally, a portable toilet device for care is used for a person who needs care. This portable toilet device is often in the form of a stool type (Western type) where a user sits down on a toilet seat. The portable toilet device generally has a form including a container for receiving and discharging filth and a form in which filth drainage is performed under natural flow.

  Patent Document 1 proposes a toilet apparatus including a stirring means and a high-pressure air tank as a means for forcibly discharging in a place where a drain pipe gradient cannot be obtained. According to this toilet apparatus, the toilet body is hermetically sealed, the filth is fluidized by the stirring means provided in the toilet body, and the filth fluid is discharged from the toilet with high-pressure air.

  Patent Document 2 discloses a toilet apparatus including an air compressor. According to this toilet device, after the filth is pulverized and fluidized by the pulverizer, the compressed air is fed into the pulverizer by the air compressor and the filth fluid is discharged.

Patent No. 3985344 JP 2008-86880 A

  By the way, according to patent document 1 which concerns on a prior art example, when sending the filth fluid in a toilet bowl main body with compressed air, it is necessary to make the inside of a toilet bowl sealed with an opening-and-closing lid. Compressed air is sent in a state in which the toilet body is sealed by the opening / closing lid, and the waste fluid is pumped and discharged. In order to seal the compressed air in the toilet body, it is necessary to increase the sealing accuracy of the opening / closing lid. Further, it is necessary to increase the strength of the toilet body so that it can withstand the pressure of the compressed air, and the structure of the toilet body may be complicated.

  According to Patent Document 2, when the filth fluid in the pulverizer is pumped by compressed air, the pulverizer needs to be sealed with an open / close lid. Compressed air is sent in a state in which the inside of the pulverizer is sealed by the opening / closing lid, and the filth fluid is pumped and discharged. In order to seal the compressed air in the pulverizer, it is necessary to increase the sealing accuracy of the open / close lid. Furthermore, it is necessary to increase the strength of the pulverizer so that it can withstand the pressure of the compressed air, and the structure inside the pulverizer may be complicated.

  Therefore, the present invention has solved the problems related to the conventional example, and devised a method for pumping the filth fluid to simplify the mechanism and to discharge the filth fluid with high accuracy. An object is to provide an apparatus.

  In order to solve the above-described problems, a toilet apparatus according to the present invention is provided with a toilet body that is provided so that washing water can flow in and receives excreted waste, and is provided at a lower portion of the toilet body. A pulverizing mechanism for pulverizing the filth together with water, an openable / closable inlet through which the filth fluid pulverized by the pulverizing mechanism flows, and a discharge pipe member connected to the discharge pipe member for guiding the filth fluid to a disposal site And a tank portion provided so as to be filled with compressed air.

  According to the toilet apparatus according to the present invention, the crushing mechanism provided in the lower part of the toilet body main body crushes the filth together with the washing water. The tank part receives the waste fluid pulverized by the pulverization mechanism from an inflowable inlet. The tank part is filled with compressed air and discharges the filth fluid from the discharge pipe member connected to the discharge port to the disposal site. For example, the tank unit opens the inlet when the filth fluid starts to flow into the inside from the crushing mechanism, closes the inlet after flowing into the filth fluid, and compresses the inlet. Air is filled and the waste fluid is pumped from the outlet. With this configuration, since the pulverizing mechanism for pulverizing and fluidizing the filth can be separated from the mechanism for pumping the filth fluid, the pulverizing mechanism and the pumping mechanism can be simplified.

  The toilet apparatus according to the present invention includes a pulverization mechanism that pulverizes filth together with cleaning water, and a tank that can be filled with compressed air and into which the filth fluid pulverized by the pulverization mechanism flows. .

  With this configuration, the pulverizing mechanism for pulverizing and fluidizing the filth and the mechanism for pumping the filth fluid can be separated, and each mechanism can specialize in the pulverizing process or the pumping process. As a result, the crushing mechanism and the pressure feeding mechanism can be simplified, and the filth fluid can be discharged with high accuracy.

It is sectional drawing which shows the structural example of the toilet apparatus 100 for care which concerns on this invention. It is a rear view which shows the structural example of the toilet apparatus 100 for care. A and B are perspective views showing a configuration example of the opening / closing lid mechanism portion 2a of the crushing device 2. FIG. It is the disassembled perspective view seen from the upper side which shows the structural example of the stone mill mechanism 2j. It is the exploded perspective view seen from the lower part side which shows the example of composition of stone mill mechanism 2j. It is an enlarged view which shows the structural example of the volt | bolt 20d. A and B are perspective views showing a configuration example of the rotary mill 2i. 3 is a cross-sectional view from one direction showing a configuration example of the crushing device 2. FIG. It is sectional drawing from the other direction which shows the structural example and operation example of the grinding | pulverization apparatus 2. FIG. It is the disassembled perspective view seen from the upper side which shows the structural example of the stone mill mechanism 21j as other embodiment. It is the exploded perspective view seen from the lower part side which shows the example of composition of stone mill mechanism 21j. It is sectional drawing which shows the operation example of the grinding | pulverization apparatus 21 as other embodiment. A and B are diagrams showing an installation example of the discharge tool 7. A is an enlarged view showing a configuration example of the discharge tool 7, and B is a perspective view showing an exploded example of the discharge tool 7. It is a block diagram which shows the structural example of the control system of the toilet apparatus 100 for care. 6 is a timing chart showing an operation example of a control system of the care toilet device 100. 4 is a timing chart showing an example of driving a crushing motor 2s that rotates a rotary mill 2i and a rotary blade 2r of the crushing device 2. A to C are timing charts showing detailed driving examples of the crushing motor 2s.

  Next, embodiments according to the present invention will be described with reference to the drawings. FIG. 1 is a cross-sectional view illustrating a configuration example of a care toilet apparatus 100 according to the present invention. FIG. 2 is a rear view illustrating a configuration example of the care toilet apparatus 100. A nursing toilet device 100 shown in FIG. 1 is a crushing device 2 provided at a lower portion of a toilet body 1 that receives excreted waste and used toilet paper. The toilet paper is discharged after being crushed.

  The care toilet device 100 includes a toilet body 1, a crusher 2, a pressure feed tank 3, and a water supply tank 4. The water supply tank 4 stores 2-3 liters of water. A water supply electromagnetic valve 4 a is provided at the water supply port of the water supply tank 4. A water supply pipe (not shown) is provided from the water supply port of the water supply tank 4 toward the interior of the toilet body 1. By opening and closing the water supply electromagnetic valve 4a, it is controlled that the wash water stored in the water supply tank 4 flows into the toilet body 1 through the water supply pipe.

  The toilet body 1 is provided with a toilet lid 1a and a toilet seat 1b. The processing of the care toilet device 100 is started according to the opening operation of the toilet lid 1a. A crushing device 2 is disposed on the lower side of the toilet body 1. The crushing device 2 is an example of a crushing mechanism unit, and includes a storage container 22n that is an example of a container member. The storage container 22n includes an opening / closing lid mechanism 2a and a pan-shaped casing 2f. The opening / closing lid mechanism 2a is fixed with screws so as to cover the opening of the housing 2f, and seals the inside of the housing 2f.

  The opening / closing lid mechanism portion 2a has a substantially circular opening 2g at a joint portion with the toilet body 1. The opening / closing lid mechanism 2a is provided with a coupling cylinder 2d extending from the outer periphery of the opening 2g. A part of the coupling cylinder 2d is inserted into the toilet body 1 so that the toilet body 1 and the opening / closing lid mechanism 2a of the crushing device 2 are coupled.

  Inside the pulverizer 2, there is provided a stone mill (grinding mortar) mechanism 2j that pulverizes the toilet paper and filth finely. This stone mill mechanism 2j is an example of a grinding mechanism, and has a fixed mill 2h and a rotary mill 2i. The upper fixed die 2h is an example of a fixed plate member, and is fixed to the receiving container 22n in a substantially disk shape. The lower rotary mill 2i is an example of a rotating disk member, is formed in a substantially disk shape, is fixed to the shaft 23a, and rotates. The fixed mortar 2h is provided with inflow ports 2m and 2m (see FIG. 4) as an example of the first through-hole portion in the vicinity of the center portion, and filth flows along with the washing water from the inflow ports 2m and 2m to be fixed. Soil and toilet paper enter the gap between the mortar 2h and the rotary mortar 2i together with the washing water. Toilet paper and filth that have entered the gap between the fixed mortar 2h and the rotary mortar 2i are finely crushed by the concavities and convexities facing the fixed mortar 2h and the rotary mortar 2i and mixed with washing water. It becomes a high state (filtrate fluid).

  A pressure feed tank 3 is disposed below the pulverizer 2. The pressure-feed tank 3 is an example of a tank unit, and for example, a metal tank is used. The pressure feed tank 3 and the pulverizer 2 are coupled by a connecting pipe 3g. The connecting pipe 3g is provided with a pressure tank open / close electromagnetic valve 3a which is an example of an inlet. Based on the opening / closing of the pressure-feed tank opening / closing electromagnetic valve 3a, filth and toilet paper, which are finely crushed and mixed with washing water, are poured into the pressure-feed tank 3.

  The pressure feed tank 3 and the air compressor 6 shown in FIG. 2 are connected by an air pipe 3i. The air pipe 3 i is coupled to the connecting portion 3 h of the pressure feeding tank 3. The connecting portion 3h is provided with a compressed air suction electromagnetic valve 3c. The air pressure inside the pressure feed tank 3 is adjusted by opening and closing the compressed air suction electromagnetic valve 3c.

  The pressure-feed tank 3 is supported at an inclination by the support tables 3d and 3d. A discharge portion 3 e is provided at the lowest position of the pressure feed tank 3. The discharge part 3e is connected to a discharge pipe 3f via a discharge electromagnetic valve 3b which is an example of a discharge port. The terminal end of the discharge pipe 3f is connected to a toilet of the equipped toilet 5, which is an example of a waste disposal place. Based on the opening / closing of the discharge electromagnetic valve 3b, the fluidized filth in the pressure feed tank 3 is discharged to the discharge pipe 3f. In this example, the fluidized filth gathers naturally in the vicinity of the discharge part 3e provided at the lowest position of the inclined pumping tank 3. In this state, when compressed air is filled into the pressure feed tank 3 by the air compressor 6 and the discharge electromagnetic valve 3b is opened, fluidized filth is discharged from the discharge pipe 3f to the attached toilet 5.

  As described above, the nursing toilet apparatus 100 according to the present invention does not integrally include a mechanism for crushing filth and a mechanism for pumping and discharging the crushed filth, and the crushing apparatus 2 illustrated in FIGS. 1 and 2. Since it is configured as a separate body like the pressure feed tank 3, each mechanism can be simplified. That is, since the crushing device 2 has only the function of crushing the filth, it is not necessary to confine the compressed air inside the crushing device 2. Thereby, the structure of the pulverizer 2 does not require the strength to withstand the pressure of the compressed air, and further does not need to seal the compressed air. Therefore, the opening / closing lid mechanism 2a of the crushing device 2 also has a simple structure.

  Moreover, since the pressure feed tank 3 has only the function of pressure-feeding and discharging fluidized filth to the discharge pipe 3f, it can be designed specifically for the function of pressure-feeding and discharging. Thereby, compressed air leakage and air pressure shortage can be solved, and fluidized filth can be reliably pumped and discharged.

  Further, the volume of the pressure feed tank 3 can be set to a sufficient volume as long as it satisfies the volume required for storing fluidized filth and the volume required for filling with compressed air. Thereby, the volume of the pressure feed tank 3 which needs to be firmly provided by the action of the pressure of the compressed air can be reduced as a necessary minimum volume. Therefore, the pressure feed tank 3 can be manufactured at a light weight and at a low cost.

  In addition, since only the fluidized filth and compressed air are stored inside the pressure feed tank 3 and the crushing device 2 is not provided, a general-purpose tank member is applied as a member of the pressure feed tank 3. Can be provided at low cost.

  Next, the configuration of the opening / closing lid mechanism 2a of the crushing device 2 will be described in detail. FIG. 3A is a front side perspective view showing a configuration example of the opening / closing lid mechanism 2a of the crushing device 2. FIG. FIG. 3B is a perspective view of the rear surface side showing a configuration example of the opening / closing lid mechanism 2a of the crushing device 2.

  The opening / closing lid mechanism 2a shown in FIGS. 3A and 3B includes a disk portion 22r, a coupling cylinder 2d, a substantially circular opening 2g, an opening / closing lid 2b, and an opening / closing motor 2c. The coupling cylinder 2 d extends from the outer periphery of the opening 2 g and is coupled to the toilet body 1. The opening / closing lid 2b is formed in a substantially fan shape, and the narrow portion of the opening / closing lid 2b is coupled to the shaft member 2e of the opening / closing motor 2c. The opening / closing lid 2b rotates with the rotation of the shaft member 2e of the opening / closing motor 2c to open and close the opening 2g. Thereby, the toilet paper, filth, and washing water which flow into the crushing device 2 from the toilet body 1 are passed or stopped.

  Next, the configuration of the stone mill mechanism 2j will be described in detail. FIG. 4 is an exploded perspective view of the stone mill mechanism 2j as viewed from above. FIG. 5 is an exploded perspective view of the stone mill mechanism 2j as viewed from below.

  The fixed mortar 2h of the stone mortar mechanism 2j includes two inflow ports 2m and 2m, an insertion hole 20c, four projecting plates 2n, and an uneven surface 22p, each having an approximately half moon shape, which is an example of a first through-hole portion. The protruding plates 2n of the fixed mortar 2h are provided at four locations around the main body 20m with equal intervals. These protruding plates 2n are fitted into the groove 2p (see FIG. 8) of the storage container 22n.

  An insertion hole 20c through which the bolt 20d is inserted is provided at the center of the main body 20m of the fixed die 2h. FIG. 6 is an enlarged view showing a configuration example of the bolt 20d. The cylindrical portion 20q of the bolt 20d shown in FIG. 6 is inserted through the insertion hole 20c.

  In the central region of the main body 20m of the fixed mortar 2h, inflow ports 2m and 2m into which toilet paper, filth, and washing water flow are provided. The filth and the like flowing in from the inlets 2m and 2m enter the gap between the fixed die 2h and the rotary die 2i.

  An uneven surface 22p is provided on one side surface of the main body 20m as shown in FIG. The uneven surface 22p is an example of a second uneven surface, and includes a plurality of convex portions 20h and a plurality of concave portions 20i. The region of the concavo-convex surface 22p is divided into six, and the extending direction of the convex portion 20h and the concave portion 20i is changed for each ６ region. Of the six divided regions, the regions facing each other through the insertion hole 20c are formed in the same extending direction of the convex portion 20h and the concave portion 20i. For example, the projections 20h and recesses 20i of the region 20s shown in FIG. 5 and the projections 20h and recesses 20i of the region 20t are formed to extend in the same direction.

  The rotary mill 2i of the stone mill mechanism 2j includes four outlets 20u, which are examples of second through-hole portions, a non-circular insertion hole 20w, two stirring blades 20g and 20g, and an uneven surface 22q. The stirring blades 20g and 20g of the rotary mill 2i are provided substantially in parallel at two locations on the bottom surface side of the main body 20v. These stirring blades 20g, 20g generate a water flow toward the outside while stirring the toilet paper, the filth, and the washing water in the container 22n of the crushing device 2, and circulate the filth and the like.

  A non-circular insertion hole 20w through which the bolt 20d is inserted is provided at the center of the main body 20v of the rotary mill 2i. The non-cylindrical portion 20r of the bolt 20d shown in FIG. 6 is inserted through the insertion hole 20w. The gap between the rotary die 2i and the fixed die 2h is adjusted by a bolt 20d. For example, the vertical position of the rotary die 2i is defined by the flat portion 21a of the bolt 20d, and the vertical position of the fixed die 2h is defined by the flat portion 21b of the bolt 20d. That is, the gap between the rotary die 2i and the fixed die 2h is determined by the distance between the flat portion 21a and the flat portion 21b.

  As shown in FIGS. 7A and 7B, in the central region of the rotary mill 2i, outlets 20u as an example of second through holes through which toilet paper, filth, and washing water flow out are provided at four locations. 7A and 7B are perspective views of the rotary mill 2i viewed from another angle. The filth having a size that cannot enter the gap between the uneven surface 22p of the fixed die 2h and the uneven surface 22q of the rotary die 2i flows out from the outlet 20u and flows into the inlets 2m and 2m of the fixed die 2h again.

  An uneven surface 22q is provided on one side surface of the main body 20v of the rotary mill 2i as shown in FIG. The uneven surface 22q is an example of a first uneven surface, and includes a plurality of convex portions 20j and a plurality of concave portions 20k. The region of the concavo-convex surface 22q is divided into six, and the extending direction of the convex portion 20j and the concave portion 20k is changed for each 領域 region. Of the six divided regions, the regions facing each other through the insertion hole 20w are formed so that the extending directions of the convex portion 20j and the concave portion 20k are the same. For example, the convex portion 20j and the concave portion 20k of the region 20x shown in FIG. 4 and the convex portion 20j and the concave portion 20k of the region 20y are formed to extend in the same direction.

  Above the stone mill mechanism 2j, a rough crushing rotary blade 2r is rotatably arranged so as to overlap with at least a part of the inlets 2m, 2m of the fixed mill 2h. The hole 21y of the rotary blade 2r is fitted into the notch 20p of the bolt 20d shown in FIG. The rough crushing rotary blade 2r is formed by bending both ends 20z and 20z of a plate-like member substantially at a right angle. The rotary blade 2r roughly crushes the filth before it is finely crushed by the stone mill mechanism 2j to form a fluid.

  Next, the configuration and operation of the pulverizer 2 will be described in detail. FIG. 8 is a cross-sectional view from one direction showing a configuration example of the pulverizing apparatus 2. FIG. 9 is a cross-sectional view from another direction showing a configuration example and an operation example of the crushing device 2. The fixed mortar 2h and the rotary mortar 2i of the pulverizing apparatus 2 are arranged to face each other.

  The crushing device 2 includes a crushing motor 2s, a first pulley 2y, a second pulley 20a, and a belt 2z as a mechanism for driving the rotary blade 2r and the rotary mill 2i described above. A pinion gear 2t is fixed to the rotating shaft of the crushing motor 2s. The tip of the shaft extending from the pinion gear 2t is rotatably attached to the guide plate 2v. A spur gear 2w is meshed with the pinion gear 2t. A first pulley 2y is fixed to the spur gear 2w so as to be able to rotate synchronously. The spur gear 2w and the first pulley 2y are rotatably attached to the shaft member 2x. The tip of the shaft member 2x is fixed to the guide plate 2v. A belt 2z is wound around the first pulley 2y and the second pulley 20a. A shaft 20b is fixed to the central portion of the second pulley 20a. A bolt 20d is welded and connected to the shaft 20b by means such as friction welding to form a shaft 23a. A screw part 20n is provided at the tip of the bolt 20d, and a rotary mill 2i and a rough crushing rotary blade 2r are fixed to the bolt 20d by screwing a nut 23b into the screw part 20n.

  When the crushing motor 2s is rotated by configuring the crushing device 2 in this manner, the rotary mill 2i and the rough crushing rotary blade 2r rotate. That is, when the crushing motor 2s is rotated, the first pulley 2y is rotated via the pinion gear 2t and the spur gear 2w. As the first pulley 2y rotates, the second pulley 20a rotates through the belt 2z and the shaft 23a rotates. As a result, the rotary mill 2i and the rough crushing rotary blade 2r fixed to the bolt 20d constituting the shaft 23a rotate. The rough crushing rotary blade 2r roughly crushes the toilet paper and the filth before crushing the filth finely with the stone mill mechanism 2j to form a fluid.

  The protruding plate 2n of the fixed mortar 2h of the stone mortar mechanism 2j is fitted and fixed to the groove 2p of the receiving container 22n. The insertion hole 20c of the fixed mortar 2h is inserted through the bolt 20d. The bolt 20d rotates idly with respect to the fixed die 2h.

  A stopper 20f and a compression spring 2q are provided on the shaft member 2e of the opening / closing motor 2c in the opening / closing lid mechanism 2a of the crushing device 2 shown in FIG. In addition, an opening / closing lid 2b is attached to the distal end side of the shaft member 2e via an opening / closing lid mechanism 2a. The opening / closing lid 2b is in close contact with the back surface of the disk portion 22r of the opening / closing lid mechanism portion 2a by the urging force of the compression spring 2q. The opening / closing lid 2b rotates with the rotation of the shaft member 2e of the opening / closing motor 2c to open / close the opening 2g (see FIG. 3A).

  The crushing device 2 is connected to the pressure feed tank 3 by a connecting pipe 3g shown in FIG. The connecting pipe 3g is provided with a pressure tank open / close solenoid valve 3a. Based on the opening and closing of the valve 3j of the pressure-feed tank opening / closing electromagnetic valve 3a, the filth that has been finely crushed and fluidized is poured into the pressure-feed tank 3. In this example, when pouring fluidized filth into the pressure feed tank 3, the rotary blade 2i is rotated at a low speed while the valve 3j of the pressure feed tank opening / closing electromagnetic valve 3a is opened, and the stirring blades 20g, 20g of the rotary die 2i are rotated. As a result, the fluidized filth is sent out from the connecting pipe 3g to the pressure feed tank 3. Thereby, the filth collected at the bottom of the container 22n of the crushing device 2 can be sent out to the pumping tank 3 evenly.

  The bottom of the container 22n is inclined toward the valve 3j. Due to this inclination, the fluidized filth naturally flows into the valve 3 j and flows down to the pressure feed tank 3. For this reason, when the waste material fluidized by opening the valve 3j flows down to the pressure feed tank 3, the fluidized waste material does not necessarily have to be sent out by the stirring blades 20g and 20g of the rotary mill 2i. However, the time for which the fluidized filth flows down to the pumping tank 3 can be shortened by sending out the filthated fluid by the stirring blades 20g and 20g of the rotary mill 2i.

  Moreover, as shown in FIG. 9, the crushing apparatus 2 stirs filth and washing water with the stirring blades 20g and 20g of the rotary mill 2i. By stirring the filth and the washing water with the stirring blades 20g and 20g, a circulating flow P1 such as convection is generated as shown in FIG.

  That is, the cleaning water is agitated by the stirring blades 20g and 20g, so that the cleaning water is sent to the inner wall surface side of the storage container 22n. At this time, the washing water sent out by the stirring blades 20g, 20g forms a spiral flow centering on the central portion (insertion hole 20w) of the rotary mill 2i, and a circulating flow P1 is generated. Further, the toilet paper and filth, together with the washing water, pass through the inlets 2m and 2m of the fixed die 2h shown in FIG. 4 and pass through the outlet 20u (see FIG. 7A) of the rotary die 2i to form a circulating flow P1. At the same time, toilet paper, dirt, and a part of the washing water also flow into the gap between the uneven surface 22p of the fixed mortar 2h and the uneven surface 22q of the rotating mortar 2i, as indicated by a broken line arrow P2 in FIG. Toilet paper that has entered the gap between the fixed die 2h and the rotary die 2i by the relative rotation of the convex portion 20h and the concave portion 20i of the fixed die 2h and the convex portion 20j and the concave portion 20k of the rotary die 2i shown in FIG. The filth is crushed finely. The crushed filth and the like are sent out toward the inner wall surface of the storage container 22n as indicated by a broken line arrow P2.

  Further, the filth having a size that cannot enter between the concave portion 20i of the fixed die 2h and the concave portion 20k of the rotary die 2i shown in FIG. 4 is supplied to the rotary die 2i from the four outlets 20u (see FIG. 7A) in the rotary die 2i. Can be sent downward. The large filth sent out from the outlet 20u rides on the flow of the circulating flow P1 along with the washing water, rises along the inner wall surface of the container 22n, flows into the rough crushing rotary blade 2r side, and is roughly crushed. It is finely crushed by the rotary blade 2r.

  Thus, since toilet paper, filth, and cleaning water stored in the storage container 22n circulate inside the storage container 22n, while the rotary mill 2i is driven to rotate, the filth and the concavo-convex surface 22p and the concavo-convex surface together with the cleaning water. It flows into the gap of the surface 22q many times. As a result, the filth is crushed several times by the relative rotation of the concavo-convex surface 22p and the concavo-convex surface 22q. Therefore, even filth containing solid matter such as beans and fiber vegetables that are difficult to pulverize can be finely pulverized. Moreover, since toilet paper, filth, and washing water circulate, the finely pulverized filth, toilet paper, and washing water are suitably mixed, and the filth and the like can be brought into a highly fluid state. Thereby, since the pipe diameter of the discharge pipe 3f can be reduced, it can be made inconspicuous when the discharge pipe 3f is provided, and the aesthetic appearance in the room is not impaired. Further, since the discharge pipe 3f is thin, it is easy to bend the discharge pipe 3f, and the work of drawing and arranging the discharge pipe 3f can be easily performed.

  Then, the structure of the stone mill mechanism 21j as other embodiment is demonstrated in detail. FIG. 10 is an exploded perspective view of the stone mill mechanism 21j as seen from above. FIG. 11 is an exploded perspective view of the stone mill mechanism 21j as viewed from below.

  The main difference in structure from the stone mill mechanism 2j shown in FIG. 4 is that the fixed mill 21h shown in FIG. 10 includes circulation flow promotion plates 21na and 21nb that promote the generation of the circulation flow. Further, the rotary mill 21i shown in FIG. 10 does not include the outlet 20u shown in FIG.

  A fixed mortar 21h of the stone mortar mechanism 21j shown in FIG. 10 includes two inflow ports 21m and 21m, an insertion hole 22c, four circulation flow promotion plates 21na and 21nb, and an uneven surface 22s that form a substantially semilunar shape. Circulating flow promoting plates 21na and 21nb of the fixed mortar 21h are installed from the inner wall portion of the container 22n shown in FIG. 12 toward the center of the container 22n, and the cleaning water circulated by the stirring blades 22g and 22g is fixed to the fixed mortar. Turn to 21m, 21m at 21h. The circulation flow promotion plates 21na and 21nb are erected at four locations on the outer peripheral portion of the fixed mortar 21h, and are fitted into groove portions 2p (see FIG. 12) provided on the inner wall portion of the storage container 22n. The groove 2p is an example of an attachment part.

  The circulation flow promotion plate 21na is formed larger than the circulation flow promotion plate 21nb, and contributes to further promoting the generation of the circulation flow. Of course, even if the four circulation flow promotion plates 21nb are used as the circulation flow promotion plate, a corresponding effect in promoting the circulation flow can be exhibited. Further, when four circulation flow promotion plates 21na are used as the circulation flow promotion plate, a remarkable effect in promoting the circulation flow can be exhibited. Further, even if the circulation flow promotion plates 21na and 21nb shown in FIG. 10 are applied in place of the four projection plates 2n shown in FIG. 4, the effect of promoting the generation of the circulation flow P1 as in the embodiment shown in FIG. Can be demonstrated.

  The plane portions 22pa and 22pb of these circulation flow promotion plates 21na and 21nb are extended so as to be directed toward the inflow ports 21m and 21m located at the center of the substantially circular main body 22m. The circulation flow promotion plates 21na and 21nb have an action of promoting the generation of the circulation flow P1 shown in FIG. In this example, toilet paper, filth, and washing water hit the circulation flow promotion plates 21na, 21nb, so that the direction in which the toilet paper, filth, and washing water flows is toward the inlets 21m, 21m located in the center of the main body 22m. Directed. Thereby, filth, washing water, etc. can be sent into inflow mouths 21m and 21m vigorously. Toilet paper and filth entered through the inlets 21m and 21m enter the gap between the uneven surface 22s of the fixed mortar 21h and the uneven surface 22t of the rotating mortar 21i, and are finely ground and fluidized.

  An insertion hole 22c through which the bolt 20d is inserted is provided at the center of the main body 22m of the fixed die 21h. The cylindrical portion 20q of the bolt 20d shown in FIG. 6 is inserted into the insertion hole 22c.

  As shown in FIG. 11, an uneven surface 22s is provided on one side surface of the main body 22m. The uneven surface 22s is composed of a plurality of convex portions 22h and a plurality of concave portions 22i. The region of the concavo-convex surface 22s is divided into six, and the extending direction of the convex portion 22h and the concave portion 22i is changed by 1/6 region. Of the six divided regions, the regions facing each other through the insertion hole 22c are formed in the same direction in which the convex portions 22h and the concave portions 22i extend.

  The rotary mill 21i of the stone mill mechanism 21j includes a non-circular insertion hole 22w, two stirring blades 22g and 22g, and an uneven surface 22t. The stirring blades 22g and 22g of the rotary mill 21i are provided substantially in parallel at two locations on the bottom surface side of the main body 22v. These stirring blades 22g and 22g stir the toilet paper, the filth, and the washing water in the container 22n of the crushing device 2.

  A non-circular insertion hole 22w through which the bolt 20d is inserted is provided at the center of the main body 22v of the rotary mill 21i. The non-cylindrical portion 20r of the bolt 20d is inserted through the insertion hole 22w.

  An uneven surface 22t is provided on one side surface of the main body 22v of the rotary mill 21i as shown in FIG. The uneven surface 22t is composed of a plurality of convex portions 22j and a plurality of concave portions 22k. The region of the uneven surface 22t is divided into six, and the extending direction of the convex portion 22j and the concave portion 22k is changed by 1/6 region. Of the six divided regions, the regions facing each other through the insertion hole 22w are formed so that the extending directions of the convex portion 22j and the concave portion 22k are the same.

  A rotary blade 21r for rough crushing is installed on the upper part of the stone mill mechanism 21j. The hole 22y of the rotary blade 21r is fitted into the notch 20p of the bolt 20d shown in FIG. The rough crushing rotary blade 21r is substantially S-shaped. The rotary blade 21r roughly crushes the toilet paper and the filth before crushing the filth finely with the stone mill mechanism 21j to form a fluid.

  FIG. 12 is a cross-sectional view showing an operation example of the crushing device 21 using the stone mill mechanism 21j. The fixed mortar 21h and the rotary mortar 21i of the pulverizing apparatus 21 are arranged to face each other. The crushing device 21 stirs filth and washing water with the stirring blades 22g and 22g of the rotary mill 21i. By stirring the filth and the washing water with the stirring blades 22g and 22g (see FIG. 11), a circulating flow P3 like convection is generated as shown in FIG. That is, the cleaning water is agitated by the stirring blades 22g and 22g, so that the cleaning water is sent to the inner wall surface side of the container 22n. At this time, the washing water sent out by the stirring blades 20g, 20g forms a spiral flow centering on the central portion (insertion hole 22w) of the rotary mill 21i to generate a circulating flow P3.

  Further, the wash water that forms the circulation flow P3 hits the flat surface portions 22pa and 22pb of the circulation flow promotion plates 21na and 21nb together with filth and toilet paper, and the flow direction of the wash water is the inlet 21m located at the center of the main body 22m, It is aimed at 21m. Thereby, circulation of washing water, filth, and toilet paper is promoted. The filth and toilet paper flowing toward the inflow ports 21m and 21m are crushed by the rotary blade 21r for rough crushing. The crushed filth and toilet paper flow into the inlets 21m and 21m of the fixed mortar 21h together with the washing water. Toilet paper and filth flowing into the inflow ports 21m and 21m flow into the gap between the uneven surface 22s of the fixed mortar 21h and the uneven surface 22t of the rotating mortar 21i, and are finely crushed to form a fluid.

  In this example, the circulation flow promotion plates 21na and 21nb are provided on the fixed die 21h. However, they may be provided on the inner wall surface of the storage container 22n. In this case, the circulation flow promotion plate is configured to extend from the inner wall surface of the storage container 22n toward the center of the storage container 22n.

  Next, a method of installing the discharge tool 7 provided at the end of the discharge pipe 3f shown in FIG. 1 on the toilet body 5a of the equipped toilet 5 will be described. FIG. 13A is an overall view of the equipped toilet 5 showing an installation example of the discharge tool 7. FIG. 13B is a partial cross-sectional view of the equipped toilet 5 showing an installation example of the discharge tool 7. A discharge tool 7 is installed on the inner wall portion 5e of the toilet body 5a of the equipped toilet 5 shown in FIG. 13B.

  In this example, a discharge pipe support member 5f having an approximately “7” shape of Arabic numerals is hooked on the edge of the toilet body 5a. The discharge pipe 3f in the vicinity of the discharge tool 7 is sandwiched and held by a holding portion 5g provided at the tip of the discharge pipe support member 5f.

  FIG. 13A shows the middle of the discharge pipe 3f, but the pressure feed tank 3 shown in FIG. 1 is connected to the end of the portion where the illustration of the discharge pipe 3f is omitted. When the discharge solenoid valve 3b of the pressure feed tank 3 is opened, the fluidized filth in the pressure feed tank 3 is discharged from the discharge tool 7 through the discharge pipe 3f. After discharging the fluidized filth from the discharge tool 7, wash water is poured from a water supply tank (not shown) of the equipped toilet 5. In this case, the cleaning water may be flowed from the water supply tank by manual operation, or the cleaning water may be flowed from the water supply tank by automatic control. In the case of automatic control, a device for automatically flowing the washing water from the water supply tank is installed, and the device for automatically flowing is operated after closing the discharge electromagnetic valve 3b of the pressure feeding tank 3.

  FIG. 13A shows a state where the toilet seat 5b of the equipped toilet 5 is lowered. The discharge pipe 3f of the discharge tool 7 shown in FIG. 13A is accommodated in the gap between the toilet seat 5b and the toilet body 5a. For example, as shown in FIG. 13B, the toilet seat 5b has a plurality of protrusions 5d. The protrusion 5d creates a gap between the toilet seat 5b and the inner wall 5e of the toilet body 5a. Since the discharge pipe 3 f of the discharge tool 7 is accommodated in this gap, it can be easily installed in the equipped toilet 5.

  FIG. 14A is an enlarged view showing a configuration example of the discharge tool 7. The discharge tool 7 shown in FIG. 14A is formed in a trapezoidal shape, and a discharge pipe 3f is connected to the inlet portion 7h. The discharge tool 7 includes an upper lid portion 7a and a lower lid portion 7b. The upper lid portion 7a and the lower lid portion 7b are fixed by four screws 7j.

  FIG. 14B is a perspective view illustrating an exploded example of the discharge tool 7. 14B includes buffer plates 7c to 7f and a discharge port 7g. The buffer plates 7c to 7f are installed so that a part of the adjacent buffer plates overlap each other with a predetermined distance from the inlet portion 7h. That is, the buffer plate 7c and the buffer plate 7d partially overlap each other. This is for suppressing the momentum at the time of discharge | emission of the fluidized waste material so that the fluidized waste material discharged | emitted via the discharge pipe 3f with compressed air from the pumping tank 3 may not scatter. The filth whose flow is suppressed by the buffer plates 7c to 7f is discharged from the discharge port 7g.

  Thus, since filth is not discharged | emitted vigorously from the discharge port 7g, it can be poured reliably into the inside of the toilet body 5a (refer FIG. 13A) of the equipped toilet 5. FIG.

  The upper lid portion 7a has the same configuration as the lower lid portion 7b. That is, the upper lid portion 7a includes buffer plates 7c to 7f and a discharge port 7g, and the buffer plates 7c to 7f of the upper lid portion 7a are installed at the same positions as the buffer plates 7c to 7f of the lower lid portion 7b. Moreover, the discharge port 7g of the upper cover part 7a is also installed in the same position as the discharge port 7g of the lower cover part 7b.

  Subsequently, a control system of the care toilet apparatus 100 will be described. FIG. 15 is a block diagram illustrating a configuration example of a control system of the care toilet apparatus 100. The care toilet apparatus 100 shown in FIG. 15 has a control unit 8. Although not shown, the control unit 8 includes a memory such as a ROM (Read Only Memory) or a RAM (Random Access Memory), a CPU (Central Processing Unit) having a calculation function, and an interface.

  The toilet lid opening / closing detection sensor 1c is connected to the control unit 8. The toilet lid opening / closing detection sensor 1c is, for example, a transmission type sensor. The slit of the slit disk that rotates in response to the opening / closing of the toilet lid 1a shown in FIG. 1 is detected by the transmission type sensor, and the opening / closing detection signal S1c. Is output to the control unit 8. The opening / closing detection signal S1c is a signal indicating opening / closing of the toilet lid 1a.

  The control unit 8 is connected to a motor drive unit 9a and a motor drive unit 9b. The motor drive unit 9a receives the motor drive data D2c from the control unit 8, decodes the motor drive data D2c, and generates a motor control signal S2c. An opening / closing motor 2c is connected to the motor drive unit 9a. The motor drive unit 9a drives the opening / closing motor 2c based on the motor control signal S2c. When the opening / closing motor 2c rotates, the opening / closing lid 2b shown in FIG. 3B rotates to open / close the opening 2g in FIG. 3A. Thereby, the toilet paper, filth, and washing water which flow into the crushing device 2 from the toilet body 1 are passed or stopped.

  The motor drive unit 9b receives the motor drive data D2s from the control unit 8, decodes the motor drive data D2s, and generates a motor control signal S2s. A crushing motor 2s is connected to the motor drive unit 9b. The motor drive unit 9b drives the crushing motor 2s based on the motor control signal S2s. When the crushing motor 2s rotates, the rotary mill 2i and the rotary blade 2r shown in FIG. 8 and the rotary mill 2i and the rotary blade 21r shown in FIG. 10 rotate to crush the filth.

  The control unit 8 is connected to a pressure feed tank opening / closing solenoid valve 3a, a water supply solenoid valve 4a, a compressed air suction solenoid valve 3c, a discharge solenoid valve 3b, and an air compressor 6.

  The pressure feed tank opening / closing electromagnetic valve 3a receives a control signal S3a from the control unit 8, and opens / closes based on the control signal S3a. When the pressure-feed tank opening / closing electromagnetic valve 3 a is opened, fluidized filth present inside the pulverizer 2 flows into the pressure-feed tank 3.

  The water supply electromagnetic valve 4a receives a control signal S4a from the control unit 8, and opens and closes based on the control signal S4a. When the water supply electromagnetic valve 4a is opened, the wash water stored in the water supply tank 4 flows into the toilet body 1 through the water supply pipe.

  The compressed air suction electromagnetic valve 3c receives a control signal S3c from the control unit 8, and opens and closes based on the control signal S3c. When the compressed air suction electromagnetic valve 3c is opened, compressed air is supplied from the air compressor 6 to the pressure feed tank 3 through the air pipe 3i.

  The discharge solenoid valve 3b receives a control signal S3b from the control unit 8, and opens and closes based on the control signal S3b. When the discharge solenoid valve 3b is opened, the fluidized filth in the pressure feed tank 3 is discharged to the attached toilet 5 through the discharge pipe 3f. The air compressor 6 receives a control signal S6 from the control unit 8, and compresses air based on the control signal S6.

  Subsequently, the operation of the control system of the care toilet apparatus 100 will be described. FIG. 16 is a timing chart showing an operation example of the control system of the care toilet apparatus 100. The care toilet device 100 operates based on the time of “CLK” shown in FIG. 16. In this example, all the solenoid valves are closed in a standby state before the operation of the nursing toilet apparatus 100 starts. In this standby state, the toilet lid 1a is closed. When the toilet lid 1a is opened by the user, the operation of the control system starts.

  At time t1 shown in FIG. 16, the toilet lid opening / closing detection sensor 1c shown in FIG. 15 detects that the toilet lid 1a is opened, and sends an opening / closing detection signal S1c indicating that the toilet lid 1a is opened to the control unit 8. Output. Further, the opening / closing lid 2b shown in FIG. 3B is rotated to open the opening 2g in FIG. 3A. As a result, toilet paper, filth, and washing water can flow from the toilet body 1 to the crushing device 2.

  At time t2, the water supply electromagnetic valve 4a is opened, and the wash water stored in the water supply tank 4 flows from the water supply pipe through the toilet body 1 into the pulverizer 2 to be stored water. At time t <b> 3, the water supply electromagnetic valve 4 a is closed to stop supplying the cleaning water in the water supply tank 4 to the pulverizer 2. As a result, a certain amount of washing water is accumulated in the pulverizer 2. The washing water supplied at this time wets the inside of the toilet body 1 and the inside of the crushing device 2. Thereby, the excreted filth becomes difficult to adhere to the inside of the toilet body 1 and the crushing device 2. The user completes the service in this state. The excreted filth and used toilet paper are stored in the toilet body 1 and the crushing device 2.

  When the user's stool is completed and the toilet lid 1a is closed, the toilet lid opening / closing detection sensor 1c shown in FIG. 15 detects that the toilet lid 1a is closed at time t4, and the toilet lid is opened. An open / close detection signal S1c indicating that 1a is closed is output to the control unit 8. When the toilet lid 1a is closed, the water supply electromagnetic valve 4a is opened, and the washing water of the water supply tank 4 is poured into the toilet body 1 and the crushing device 2 from the water supply pipe.

  At time t <b> 5, the water supply electromagnetic valve 4 a is closed to stop the flush water in the water supply tank 4 from flowing into the toilet body 1 and the pulverizer 2. Thereby, the filth and the used toilet paper stored in the toilet body 1 are poured into the crushing device 2. The opening / closing lid 2b shown in FIG. 3B is rotated to close the opening 2g in FIG. 3A. In a state where filth, used toilet paper and washing water are stored in the pulverizer 2, the rotary mill 2i and the rotary blade 2r shown in FIG. 8 are rotated to finely crush the toilet paper and filth together with the washing water. Fluidize. For example, the rough crushing rotary blade 2r roughly crushes toilet paper and filth. Then, the fixed mill 2h and the rotary mill 2i shown in FIG. 9 rotate relative to each other, so that the toilet paper and filth that have entered the gap between the fixed mill 2h and the rotary mill 2i are finely crushed into a fluid.

  At time t <b> 6, the pressure tank open / close electromagnetic valve 3 a is opened, and the fluidized filth inside the pulverizer 2 is poured into the pressure tank 3. In this example, as shown in FIG. 9, the rotating mortar 2i of the pulverizing apparatus 2 is rotated at a low speed, and the filth that has been fluidized by the stirring blades 20g and 20g of the rotating mortar 2i is transferred from the connecting pipe 3g to the pressure feed tank 3. Send it out.

  At time t7, the pressure tank open / close solenoid valve 3a is closed. Also, the air compressor 6 is started. At time t8, the compressed air suction electromagnetic valve 3c is opened, and compressed air is supplied from the air compressor 6 to the pressure feed tank 3 through the air pipe 3i. At time t9, the discharge electromagnetic valve 3b is opened, and the filth in the pressure feed tank 3 is discharged from the discharge pipe 3f to the toilet 5 with compressed air.

  At time t11, the air compressor 6 is stopped and the compressed air suction electromagnetic valve 3c is closed. As a result, the supply of compressed air from the air compressor 6 to the pressure feed tank 3 is stopped. Further, the discharge electromagnetic valve 3b is closed, and the discharge from the pressure tank 3 to the toilet 5 is stopped. At this time, all the filth that has been fluidized in the pressure-feed tank 3 is discharged to the equipped toilet 5.

  On the other hand, at time t7, the cleaning operation is started. The rotation of the rotary mill 2i that sends out the filth in the pulverizer 2 is stopped and the pressure tank open / close solenoid valve 3a is closed. Further, the opening / closing lid 2b shown in FIG. 3B is rotated to open the opening 2g in FIG. 3A, and the water supply electromagnetic valve 4a is opened to allow the cleaning water in the water supply tank 4 to flow into the pulverizer 2.

  At time t10, the opening / closing lid 2b shown in FIG. 3B is rotated to close the opening 2g in FIG. 3A and the water supply electromagnetic valve 4a is closed to stop the supply of cleaning water from the water supply tank 4 to the pulverizer 2. To do. At this time, a fixed amount of washing water is stored in the storage container 22n of the pulverizing apparatus 2. In this state, the rotary mill 2i and the rotary blade 2r shown in FIG.

  At the time t12, the rotary mill 2i and the rotary blade 2r of the pulverizer 2 are stopped, and the pressure feed tank opening / closing electromagnetic valve 3a is opened, and the rinse water after washing in the pulverizer 2 is poured into the pressure feed tank 3. At time t13, the pressure tank open / close solenoid valve 3a is closed and the air compressor 6 is started.

  At time t14, the compressed air suction electromagnetic valve 3c is opened, and compressed air is supplied from the air compressor 6 to the pressure feed tank 3 through the air pipe 3i. Further, the discharge electromagnetic valve 3 b is opened, and the rinse water after washing in the pressure feed tank 3 is discharged from the discharge pipe 3 f to the attached toilet 5.

  At time t15, the air compressor 6 is stopped and the compressed air suction electromagnetic valve 3c is closed. Further, the discharge solenoid valve 3b is closed to stop the discharge of the rinsing water from the pressure feed tank 3 to the attached toilet 5. At this time, all the rinsing water in the pressure feed tank 3 is discharged to the toilet 5. This completes a series of filth treatments in the care toilet device 100.

  Then, the process which grinds the filth by the grinder 2 is demonstrated in detail. FIG. 17 is a timing chart showing an example of driving the crushing motor 2s that rotates the rotary mill 2i and the rotary blade 2r of the crushing device 2. The time T shown in FIG. 17 indicates the time T of the pulverization process in the pulverization apparatus 2 shown in FIG. 16, that is, between the time t5 and the time t7. In the pulverization process time T in the pulverization apparatus 2 shown in FIG. 17, the loosening pulverization process (time T1), the main pulverization process (time T2), and the discharge pulverization process (time T3) are performed.

  FIG. 18A is a timing chart showing an example of a loosening and pulverizing process performed during time T1 in FIG. In the loosening and pulverizing process that is performed during the time T1, the crushing motor 2s is alternately rotated in the normal direction and the reverse direction, so that the rotary mill 2i and the rotary blade 2r of the pulverizer 2 are rotated in the normal direction and the reverse direction. In this example, a DC motor is used as the crushing motor 2s, and is rotated forward or reverse in the direction of the flowing current.

  In this example, the time T1 is assumed to be about 10 seconds. As shown in FIG. 18A, the operation of rotating the crushing motor 2s in the forward direction for 0.5 seconds, then stopping for 0.5 seconds, and then rotating in the reverse direction for 0.5 seconds and stopping for 0.5 seconds is defined as one cycle. Rotation, stop, reverse rotation, stop, forward rotation,... And these operations are repeated for 5 cycles in 10 seconds. Thereby, the direction of the water flow inside the pulverizing apparatus 2 is alternately changed in the opposite direction. Therefore, the filth in the pulverizer 2 can be loosened. In this way, the direction of the water flow alternately changes in the opposite direction, so that toilet paper and washing water can be particularly quickly acclimated, and the fibers of the toilet paper are preferably loosened and water-solubilized.

  FIG. 18B is a timing chart showing an example of the main crushing process performed during time T2 in FIG. In the main crushing process performed during the time T2, the rotation width 2i and the rotary blade 2r of the crushing device 2 are rotated forward and reverse by alternately changing the time width of the crushing motor 2s.

  In this example, the time T1 is assumed to be about 96 seconds. As shown in FIG. 18B, the crushing motor 2 s is normally rotated for 10 seconds, then is stopped for 0.5 seconds, is then reversed for 5 seconds, and is stopped for 0.5 seconds. These operations of reverse rotation, stop, normal rotation,... Are repeated 6 cycles in 96 seconds. Accordingly, the rough crushing rotary blade 2r shown in FIG. 9 roughly crushes toilet paper and filth. Then, the fixed mill 2h and the rotary mill 2i shown in FIG. 9 rotate relative to each other, so that the toilet paper and filth that have entered the gap between the fixed mill 2h and the rotary mill 2i are finely crushed into a fluid.

  FIG. 18C is a timing chart showing an example of the discharge pulverization process performed during time T3 in FIG. The discharge crushing process carried out during the time T3 is performed by rotating the crushing motor 2s at a low speed in the forward direction (1/2 to 1/4 the rotation speed of the main crushing process) and rotating the mill 2i of the crushing device 2. And the rotary blade 2r is rotated.

  In this example, the time T3 is assumed to be about 30 seconds. As shown in FIG. 18C, the crushing motor 2s is rotated forward at a low speed for 30 seconds. As a result, the filth formed as a fluid is sent out from the connecting pipe 3g to the pressure feed tank 3 by the stirring blades 20g and 20g of the rotary mill 2i shown in FIG.

  Note that the bottom of the container 22n shown in FIG. 9 is inclined toward the valve 3j. Due to this inclination, the fluidized filth naturally flows into the valve 3 j and flows down to the pressure feed tank 3. For this reason, when the waste material fluidized by opening the valve 3j flows down to the pressure feed tank 3, it is not always necessary to send out the fluidized waste material by the low-speed rotation of the stirring blades 20g and 20g of the rotary mill 2i. . However, by sending out the filth that is fluidized by the stirring blades 20g and 20g of the rotary mill 2i, the time for flowing the filth that has been liquefied to the pressure feed tank 3 can be shortened to time T3 (about 30 seconds).

  In this way, at time T shown in FIGS. 16 and 17, the crushing device 2 drives the crushing motor 2 s to finely crush the toilet paper and filth to form a fluid and discharge it to the pressure feed tank 3. Note that the times T4 and T5 shown in FIG. 17 are processing intervals, the time T4 is assumed to be about 0.5 to 1.0 seconds, and the time T5 is assumed to be about 1.0 seconds.

  Thus, according to the toilet apparatus 100 for care according to the present invention, the uneven surface 22q of the rotary mill 2i in the crushing device 2 and the uneven surface 22p of the fixed mortar 2h arranged to face the uneven surface 22q, It is to crush filth.

  As a result, the filth can be finely pulverized and the filth can be brought into a highly fluid state. Therefore, since the diameter of the discharge pipe 3f that discharges filth can be reduced, the aesthetics of the room is not impaired. Further, since the discharge pipe 3f is thin, the discharge pipe 3f can be bent, and the arrangement of the discharge pipe 3f can be facilitated. Of course, the discharge pipe 3f can be prevented from being clogged.

  Further, according to the toilet device 100 for care according to the present invention, the pulverizing device 2 for pulverizing the filth together with the cleaning water, and the fluidized filth pulverized by the pulverizing device 2 can flow in and be filled with compressed air. The pressure-feed tank 3 is provided.

  With this configuration, it is possible to separate a pulverizing mechanism that pulverizes filth into a fluid and a mechanism that pumps the filth that has been liquefied, and each mechanism can specialize in pulverization or pressure feeding. As a result, the mechanism of the crushing device 2 and the pressure feed tank 3 can be simplified, and the filth that has been fluidized can be discharged with high accuracy.

  The present invention relates to a general toilet apparatus installed in a home or public facility, a portable toilet apparatus that can be simply installed and used outdoors or used for in-vehicle use, and a nursing toilet apparatus. It is very suitable when applied to.

  DESCRIPTION OF SYMBOLS 1 ... Toilet bowl main body, 2 ... Crusher (crushing mechanism part), 2h, 21h ... Fixed mortar (fixed disk member), 2i, 21i ... Rotating mortar (rotary disk member), 2m, 21m ... Inlet (first through hole), 2r, 21r ... Rough crushing rotary blade (rotating blade member), 3a ... Pressure tank open / close solenoid valve (inlet), 3b ... Discharge Solenoid valve (discharge port), 20 g, 22 g, stirring blade, 20 u, outlet (second through hole), 21 n, circulation flow promotion plate, 22 n, container (container member) ), 22p, 22s ... Uneven surface (second uneven surface), 22q, 22t ... Uneven surface (first uneven surface), 100 ... Toilet device for nursing care (toilet device)

Claims (7)

Toilet body that is provided with wash water so that it can flow in and receives the excreted waste,
A crushing mechanism provided at the lower part of the toilet body and crushing the filth with the washing water;
An openable and closable inlet through which the filth fluid pulverized by the pulverization mechanism flows in and a discharge port connected to a discharge pipe member that guides the filth fluid to a disposal site are provided so as to be filled with compressed air. And a tank unit. The tank part is
When the filth fluid starts to flow into the interior, the inflow port is opened, and the inflow into the filth fluid is completed, the inflow port is closed, and the compressed air is The toilet device according to claim 1, wherein the toilet device is filled and pumps the waste fluid from the discharge port.   After the filth fluid pulverized by the pulverizing mechanism flows into the tank from the inlet, the inlet is closed and only the washing water is supplied into the pulverizing mechanism to drive the pulverizing mechanism. The rinsing process is performed, the filth fluid inside the tank part is pumped, and the inflow port is opened, and the rinsing water for rinsing is made to flow into the tank unit, and then the inflow port is closed. The toilet apparatus according to claim 2, wherein the toilet apparatus is in a state and is filled with the compressed air, and the rinse water for rinsing is pumped from the discharge port.   After pumping the filth fluid from the discharge port of the tank unit, only the washing water is supplied into the crushing mechanism unit to drive the crushing mechanism unit to perform a rinsing process, and the inlet is opened. The inflow port is closed after the rinse water for rinsing flows into the tank portion, and the rinse water for washing is pumped from the discharge port by filling the compressed air. The toilet device according to claim 2, wherein The discharge port of the tank part is configured to be openable and closable,
The tank part is
When the filth fluid starts to flow into the interior, the inlet is opened and the outlet is closed, and after flowing into the filth fluid, the inlet is closed. The toilet apparatus according to claim 1, wherein the toilet is filled with the compressed air and the discharge port is opened to pressure-feed the filth fluid from the discharge port. The crushing mechanism part is
A container member containing a pulverizing mechanism for pulverizing the filth,
A rotating disk member that is provided inside the container member so as to be rotatable and has a substantially disk shape, has a stirring blade part that stirs the washing water, and has a first uneven surface on one side surface;
The rotating plate member is opposed to the container member and fixed to the container member. The rotating plate member has a second concavo-convex surface on one side facing the first concavo-convex surface, and a first through-hole portion in the vicinity of the center portion. The toilet device according to claim 1, further comprising a fixed plate member having the same.   7. A rotary blade member provided above the fixed plate member and disposed so as to be rotatable and driven so as to overlap with at least a part of the first through hole portion of the fixed plate member. The toilet device described.

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