JP5872759B2 - Human body cleaning device - Google Patents

Description

Aspects of the present invention generally relate to a human body cleaning apparatus including a ceramic heat exchanger provided with a plurality of heater patterns , specifically, for example, a “butt” of a user sitting on a Western-style seat toilet The present invention relates to a human body cleaning apparatus that can be used for the purpose of warming water for cleaning water.

  A heat exchanger can be used to heat an object such as water. For example, a human body cleaning device that cleans a user's “wet” or the like is provided with warm water supply means for warming the cleaning water. As one type of the hot water supply means, there is a heat exchanger that heats water flowing in a pipe made of ceramic, metal, or the like to a predetermined temperature with a heater or the like disposed therein. As one of the heating elements used in this heat exchanger, a cylindrical heating element is used. In the heat exchanger disclosed in Patent Document 1, one heater pattern is provided on a cylindrical heating element. In this heat exchanger, the temperature of hot water is controlled by turning on (ON) and turning off (OFF) energization of one heater pattern.

  However, if only one heater pattern is turned ON / OFF, the temperature of the hot water may overshoot significantly up and down around the target temperature. As a result, high-temperature or low-temperature washing water may be unexpectedly ejected from the human body washing apparatus. In order to solve this problem, a measure to devise a control circuit for the heating element can be considered. However, there arises a problem that the circuit configuration becomes complicated and the cost increases.

  Therefore, as in the heat exchanger disclosed in Patent Document 2, two heater patterns are combined into one, and a configuration that solves the above-described problems by using two heater patterns properly is known. Yes.

  However, in the configuration disclosed in Patent Document 2, the two heater patterns are merely arranged adjacent to each other. For this reason, when only any one heater pattern is used, the heater pattern side that is turned on in the heating element is strongly heated. Therefore, there is a problem that only a part of the heating element is heated strongly and unevenness occurs in the heating state of the water heated by the heating element.

JP 2001-279786 A JP-A-11-081425

The present invention has been made based on the recognition of such a problem, and even if any of the plurality of heater patterns is used , the water flowing through the flow path and the heater pattern do not come into contact with each other for a long time, It is an object of the present invention to provide a human body washing apparatus capable of obtaining washing water having a desired temperature immediately after passing water.

According to a first aspect of the present invention, a ceramic heating element having a cylindrical part provided with a plurality of heater patterns and a cylindrical part of the heating element are inserted and heated through the cylindrical part of the heating element. A heat exchanger having a case portion that forms a water flow path around the cylindrical portion, a cleaning nozzle that discharges water heated by the heat exchanger, and a plurality of heater patterns one or a combination of a plurality of heater pattern have line control of protraction of the control and the cleaning nozzle of the heating of the heating element by passing a current, for each of the plurality of heater pattern, according to the ratio of the energization time output it is possible to obtain, in the case of energizing only one of the plurality of heater pattern, the human body washing apparatus der provided with a control unit that uses a plurality of heater pattern in order The plurality of heater patterns repeat in parallel with each other along the peripheral side surface of the cylindrical portion and are folded back in the extending direction of the cylindrical portion, and each of the plurality of heater patterns overlaps itself. Without being intersected with other heater patterns, and the flow path is configured to allow the water to flow in a direction intersecting with each of the folding directions of the plurality of heater patterns, and in the center of the cylindrical portion. a human body washing apparatus characterized by having the inner wall formed in a spiral groove of the case portion to flow the water in a spiral around the shaft.

According to this human body cleaning device , if one of a plurality of heater patterns or a plurality of heater patterns is used in accordance with a target heating temperature, the number of heater patterns used is the same. The heat generation distribution around the heating element can be made uniform. Thereby, the water which flows into a flow path can be warmed without a heating nonuniformity, and the human body washing | cleaning apparatus with the stable temperature characteristic is realizable. Moreover, according to this human body washing | cleaning apparatus , the water which flows into a flow path will cross | intersect a heater pattern repeatedly. Water is repeatedly heated at a position that intersects the heater pattern. Thereby, the heated part of the water gradually expands in the flow path, and a human body washing apparatus without heat unevenness can be obtained.
Moreover, according to this human body cleaning apparatus , since it is made into the spiral flow path, the water which flows into a flow path and the heater pattern can contact for a longer time, and the human body cleaning apparatus which provides the washing water without a thermal nonuniformity It can be.

According to a second aspect of the present invention, there is provided the human body cleaning apparatus according to the first aspect, wherein outputs of the plurality of heater patterns are uniform.

According to this human body cleaning apparatus , since the heater pattern is formed so that the output is uniform, when the heater pattern to the heating element is formed by printing, the width and height of the metallization are all the same. be able to. Thereby, it is easy to print the heater pattern, and the manufacturing is simplified.

According to a third aspect of the present invention, there is provided the human body cleaning apparatus according to the first or second aspect, wherein one end of each of the plurality of heater patterns is connected to one common electrode.

According to this human body cleaning apparatus , since one common electrode is provided for a plurality of heater patterns, it is easy to form a heater pattern with a heating element even if the number of heater patterns increases. Furthermore, since the electrode terminals and electrical wiring formed on the heating element of the heater pattern in the heating element can be reduced, the entire human body cleaning apparatus can be reduced in size.

Moreover, 4th invention is further provided with the control part which controls electricity supply to each of these heater patterns in any one invention of 1st-3rd, The said control part is said heater pattern. It is a human body washing | cleaning apparatus characterized by controlling so that the electricity supply time to each of these may become equal.

According to this human body cleaning apparatus , for example, if only one heater pattern is used, it is not used biased to only one system by using in order. Thereby, it is possible to suppress the deterioration of only a specific heater pattern, and to extend the lifetime of the entire human body cleaning apparatus .

According to the aspect of the present invention, there is provided a human body cleaning device that does not generate heating unevenness even when any of a plurality of heater patterns is used, and can obtain cleaning water having a desired temperature immediately after passing water.

It is a typical sectional view which illustrates the heat exchanger concerning an embodiment of the invention. It is a typical perspective view which illustrates the heat generating body used with the heat exchanger which concerns on this Embodiment. It is a schematic plan view which illustrates the heat generating body used with the heat exchanger which concerns on this Embodiment. It is a typical top view which illustrates the layout of a heater pattern. It is a schematic diagram which illustrates the relationship between a heater pattern and the direction through which water flows. It is a typical top view which illustrates other layouts of a heater pattern. It is a typical perspective view showing the toilet apparatus provided with the human body washing | cleaning apparatus which concerns on embodiment of this invention. It is a block diagram showing the principal part structure of the human body washing | cleaning apparatus which concerns on this embodiment. It is a block diagram which illustrates the example of the principal part structure of the waterway system of the human body washing apparatus which concerns on this embodiment. It is a figure explaining the specific example of control. It is a figure explaining the specific example of control. It is a figure explaining the specific example of control.

Embodiments of the present invention will be described below with reference to the drawings. In addition, in each drawing, the same code | symbol is attached | subjected to the same component and detailed description is abbreviate | omitted suitably.
FIG. 1 is a schematic cross-sectional view illustrating a heat exchanger according to an embodiment of the invention.
FIG. 2 is a schematic perspective view illustrating a heating element used in the heat exchanger according to this embodiment.

As shown in FIG. 1, the heat exchanger 440 according to the present embodiment includes a heating element 447 and a case portion 448.
The heating element 447 has a cylindrical portion 4471.
The tubular portion 4471 is provided with a plurality of heater patterns 441a, 441b, and 441c.
In the present embodiment, the plurality of heater patterns 441a, 441b, and 441c are repeatedly folded back in parallel with each other along the peripheral side surface of the cylindrical portion 4471.

The heating element 447 is formed of ceramics, for example. The other end 4471 b side of the cylindrical portion 4471 is inserted into the case portion 448. Thereby, the flow paths 448a and 448b of the water heated by the heating element 447 are formed around the cylindrical portion 4471. The tubular portion 4471 is provided with a flange portion 4472. One end 4471 a side of the cylindrical portion 4471 extends from the flange portion 4472 to the outside of the case portion 448.

  The heating element 447 is a flange portion 4472 and is fixed to the case portion 448 by, for example, a screw. An O-ring R <b> 1 is provided between the flange portion 4472 and the case portion 448, and a sealing property between the flange portion 4472 and the case portion 448 is ensured.

A plurality of heater patterns 441a, 441b, and 441c are provided in the cylindrical portion 4471 of the heating element 447. Here, the plurality of heater patterns 441a, 441b, and 441c are collectively referred to as a heater pattern 441.
In the present embodiment, three heater patterns 441a, 441b, and 441c are provided. Note that the number of heater patterns 441 is not limited to three, and two or more heater patterns may be provided. In the present embodiment, a case where three heater patterns 441a, 441b, and 441c are provided will be described as an example.

  As shown in FIG. 2, the heater pattern 441 is provided on the side of the other end 4471 b of the cylindrical portion 4471 along the cylindrical shape. The heater pattern 441 is incorporated within the thickness of the cylindrical portion 4471, for example. More specifically, the heater pattern 441 is sandwiched between, for example, two layers of insulators.

  As shown in FIG. 1, the case portion 448 includes a case portion main body 4481 and a lid portion 4482. The case portion main body 4481 is provided with a space S in which the cylindrical portion 4471 of the heating element 447 is accommodated. A flange portion 4472 of the heating element 447 is attached to one end 4481a of the case portion main body 4481. A lid portion 4482 is fixed to the other end 4481b of the case portion main body 4481 by, for example, a screw. An O-ring R <b> 2 is provided between the lid portion 4482 and the other end 4481 b of the case portion main body 4481, and the hermeticity between the lid portion 4482 and the case portion main body 4481 is ensured.

The space S of the case portion main body 4481 is larger than the cylindrical portion 4471 of the heating element 447. In this space S, a water flow path 448 a is formed in a gap between the case main body 4481 and the lid 4482 and the cylindrical portion 4471 of the heating element 447.
In the present specification, “water” includes not only cold water but also heated hot water.

In the heat exchanger 440, while water flows through the flow path 448a, heat is transmitted from the heating element 447 heated by energizing the heater pattern 441 to the groove, and hot water having a predetermined temperature is generated.
In the heat exchanger 440 according to the present embodiment, the heat generation distribution of the heating element 447 is uniform even if any one of the plurality of heater patterns 441a, 441b, and 441c is used. A plurality of heater patterns 441a, 441b and 441c are provided. Thus, the heat exchanger 440, so that the water flowing through the channel 448a Ru can be warmed heat evenly.

FIG. 3 is a schematic plan view illustrating a heating element used in the heat exchanger according to this embodiment.
FIG. 3A is a schematic plan view illustrating the appearance of the heating element, and FIG. 3B is a schematic plan view illustrating a state in which the heater pattern is exposed.
FIG. 4 is a schematic plan view illustrating the layout of the heater pattern.

  As illustrated in FIG. 3A, the cylindrical portion 4471 of the heating element 447 includes an inner portion PA and an outer portion PB. The inner part PA and the outer part PB are formed of ceramics, for example. Further, an intermediate part PC is sandwiched between the inner part PA and the outer part PB. A heater pattern 441 is formed in the intermediate portion PC. The intermediate portion PC includes, for example, an insulating film material and a conductive heater pattern 441 provided on the film material.

FIG. 3B shows a state where the outer portion PB in FIG. 3A is removed.
When the heating element 447 is, for example, ceramics, the inner part PA is shaped by a ceramic raw material, and an intermediate part PC, which is a film material on which a heater pattern 441 is formed, is wound around the inner part PA. Furthermore, the outer part PB is modeled on the outer periphery with a ceramic raw material. When fired in this state, the heating element 447 is completed.

  In the above example, ceramic is used for the heating element 447, but the present invention is not limited to this. That is, for example, a metal may be used as a base material of the heating element 447 as long as the heater pattern 441 is insulated so as not to cause an electrical short circuit.

  An opening h is provided in the outer portion PB. From this opening h, terminals CT, Ta, Tb, and Tc that are electrically connected to the heater pattern 441 of the intermediate portion PC are exposed. The terminals CT, Ta, Tb, and Tc are disposed on the one end 4471a side of the flange portion 4472 of the cylindrical portion 4471. Thereby, when the heating element 447 is assembled to the case portion 448, the terminals CT, Ta, Tb, and Tc are arranged outside the case portion 448.

  Wiring is connected to the terminals CT, Ta, Tb, and Tc by solder or the like, respectively, and energization control from the external control unit to the heater patterns 441a, 441b, and 441c is performed.

FIG. 4 shows a state where the intermediate part PC is expanded.
Here, with the intermediate portion PC deployed, the direction along the direction in which the tubular portion 4471 extends is the x direction, and the direction along the outer circumferential direction of the tubular portion 4471 is perpendicular to the x direction when deployed. Let the direction be the y direction.

  In the intermediate portion PC, the plurality of heater patterns 441a, 441b, and 441c are provided on the film material BF serving as a base material. The intermediate part PC is, for example, a film-like wiring pattern.

  The plurality of heater patterns 441a, 441b, and 441c are provided so as to be folded back along the other heater patterns 441a, 441b, and 441c without overlapping each other and without intersecting with the other heater patterns 441a, 441b, and 441c. It has been.

  For example, the three heater patterns 441a, 441b, and 441c include a portion XP that is laid in the x direction at a constant interval and a portion YP that is laid along the y direction. Here, the portion XP is longer than the portion YP.

A plurality of sets of portions XP are provided. The plurality of sets of parts XP are arranged along the y direction. Two portions XP adjacent in the y direction are connected by a portion YP at one end side or the other end side. When three or more sets of parts XP are provided, two parts XP adjacent in the y direction are alternately connected by the parts YP at one end side and the other end side.
As a result, the three heater patterns 441a, 441b, and 441c are provided by being folded back multiple times in the x direction while maintaining parallelism, and provided over the entire y direction.

  One end of each of the three heater patterns 441a, 441b, and 441c is connected to one terminal (common terminal) CT. Each other end is connected to terminals Ta, Tb and Tc, respectively. Thereby, compared with the case where each of the heater patterns 441a, 441b and 441c is provided with two terminals, the number of terminals can be reduced, and the heat exchanger 440 can be downsized. Furthermore, even if the heater pattern is increased, the heater pattern can be easily formed on the heating element 447.

  Further, in the heat exchanger 440 according to the present embodiment, the outputs of the plurality of heater patterns 441a, 441b and 441c are uniform. For example, when 1200 W (watt) is obtained by the heating element 447, the output of each of the three heater patterns 441a, 441b, and 441c is set to 400W. Thereby, the length, width and height of each heater pattern 441a, 441b and 441c can be made uniform. When the heater pattern 441 is formed by printing, for example, when the width and height are the same, manufacturing by printing is simplified.

  In order to make the outputs of the plurality of heater patterns 441a, 441b, and 441c uniform, the resistance values of the plurality of heater patterns 441a, 441b, and 441c may be made uniform. When the width and height of the heater pattern 441 are the same, the resistance values are uniform if the lengths are the same. For example, in each of the plurality of heater patterns 441a, 441b, and 441c, by adjusting the length from the terminals Ta, Tb, and Tc to the respective folded portions, the lengths of the plurality of heater patterns 441a, 441b, and 441c, respectively. In addition, the resistance values can be made uniform.

FIG. 5 is a schematic view illustrating the relationship between the heater pattern and the direction in which water flows.
FIG. 5A illustrates a state in which water flows spirally. Here, the flow of water is indicated by the arrow W1. That is, water flows spirally around the central axis of the tubular portion 4471 of the heating element 447.

Such a flow of water is formed by the flow path 448a formed by the case portion 448 shown in FIG.
Specifically, it is as follows. As illustrated in FIG. 1, the flow path 448 a provided between the case main body 4481 and the cylindrical portion 4471 is provided in a spiral shape, for example, around the central axis of the cylindrical portion 4471. That is, a spiral groove is formed on the inner wall of the case portion main body 4481. The spiral groove communicates with a flow path 448 b provided in the case portion main body 4481.

  In the heat exchanger 440 according to this embodiment, water flows in from the one end 4471a of the cylindrical portion 4471 of the heating element 447 and flows in the cylindrical shape toward the other end 4471b (arrow A). Thereafter, water flows from the other end 4471b of the cylindrical portion 4471 into the flow path 448a, and advances spirally around the central axis of the cylindrical portion 4471. And it goes out of the case part 448 from the flow path 448b (arrow B).

  Thus, when the spiral flow path 448a is configured, the water flowing in the flow path 448a and the heater pattern 441 come into contact with each other for a longer time. As a result, the heat exchanger 440 without heat unevenness can be realized.

  FIG. 5B illustrates a state where water flows so as to intersect the heater pattern 441. Here, the flow of water is indicated by arrow W2. That is, water flows in a direction that intersects with the direction in which the heater pattern 441 is folded back.

For example, when the heater pattern 441 has the layout illustrated in FIG. 4, the folding direction of the heater pattern 441 is the x direction. In the heating element 447 provided with the heater pattern 441, water flows in a direction intersecting the x direction (for example, a direction along the outer periphery of the tubular portion 4471).
When the direction of folding the heater pattern 441 is other than the x direction, water may be flowed in a direction intersecting with the direction of folding.

  As described above, when water is caused to flow in a direction intersecting with the direction of folding of the heater pattern 441, the water repeatedly intersects with the heater pattern 441. Thereby, water is repeatedly heated at a position intersecting the heater pattern, and the heated portion of the water gradually expands in the flow path. Therefore, water can be heated without unevenness.

FIG. 6 is a schematic plan view illustrating another layout of the heater pattern.
FIG. 6 shows a state where the intermediate portion CP is expanded.
In the layout of the heater pattern 441 shown in FIG. 6A, the direction of the return of the heater pattern 441 is the y direction.

  For example, the three heater patterns 441a, 441b, and 441c include a portion XP that is laid in the x direction at a constant interval and a portion YP that is laid along the y direction. Here, the portion XP is shorter than the portion YP.

A plurality of sets of the portions YP are provided. The plurality of sets of parts YP are arranged along the x direction. Two portions YP adjacent in the x direction are connected by a portion XP on one end side or the other end side. When three or more sets of portions YP are provided, two portions YP adjacent in the x direction are alternately connected by the portions XP on one end side and the other end side.
One end of the portion YP arranged at the end is connected to the common terminal CT by a portion XP1 laid in the x direction.
As a result, the three heater patterns 441a, 441b, and 441c are provided by being folded back multiple times in the y direction while keeping parallel, and are provided over the entire y direction.

    In the layout of the heater pattern 441 shown in FIG. 6B, the direction of folding back the heater pattern 441 is the x direction.

  For example, the three heater patterns 441a, 441b, and 441c include a portion XP that is laid in the x direction at a constant interval and a portion CP that is laid in a curved manner. That is, the heater pattern 441 shown in FIG. 6B is provided with a portion CP instead of the portion YP of the heater pattern 441 shown in FIG. In this way, the portion XP may be connected by the curved portion CP.

  Note that the layout of the heater pattern 441 is not limited to these. For example, although not shown, the folded pattern may be laid out in a zigzag manner without providing the portion YP. In this case, water may be allowed to flow in a direction intersecting with the direction of each folded pattern.

  Thus, according to the heat exchanger 440 according to the present embodiment, even if any of the plurality of heater patterns 441a, 441b, and 441c is used, heating unevenness due to the heat exchanger 440 does not occur, and immediately after passing water. Wash water having a desired temperature can be obtained.

Next, a human body cleaning apparatus using the heat exchanger 440 according to this embodiment will be described.
FIG. 7 is a schematic perspective view showing a toilet apparatus provided with the human body cleaning apparatus according to the embodiment of the present invention.
Moreover, FIG. 8 is a block diagram showing the principal part structure of the human body washing | cleaning apparatus which concerns on this embodiment.
In addition, FIG. 8 represents together the principal part structure of the waterway system and the electrical system.

  The toilet device shown in FIG. 7 includes a Western-style seat toilet (hereinafter simply referred to as “toilet” for convenience of explanation) 800 and a sanitary washing device 100 provided thereon. The sanitary washing device 100 includes a casing 400, a toilet seat 200, and a toilet lid 300. The toilet seat 200 and the toilet lid 300 are pivotally supported with respect to the casing 400 so as to be freely opened and closed.

  In the casing 400, a human body cleaning device 401 that implements cleaning of a user who sits on the toilet seat 200 such as a “butt” is incorporated. The human body cleaning apparatus 401 includes a cleaning nozzle 471 that discharges water heated by the heat exchanger 440 and a control unit 405 that controls heating of the heating element 447 and extension of the cleaning nozzle 471.

  Further, for example, the casing 400 is provided with a seating detection sensor 404 that detects that the user has sat on the toilet seat 200. When the seating detection sensor 404 detects a user sitting on the toilet seat 200, when the user operates an operation unit (not shown) such as a remote controller, the cleaning nozzle 471 can be advanced into the bowl 801 of the toilet 800. it can. In the sanitary washing device 100 shown in FIG. 7, the washing nozzle 471 has entered the bowl 801.

  One or a plurality of water discharge ports 473 are provided at the tip of the cleaning nozzle 471. Then, the washing nozzle 471 can wash water such as a “buttock” of a user sitting on the toilet seat 200 by ejecting water from a water discharge port 473 provided at the tip of the washing nozzle 471.

  As shown in FIG. 8, the human body cleaning device 401 according to this embodiment includes a water supply pipe 10 that guides water supplied from a water supply source (not shown) such as a water supply or a water storage tank. A water supply valve 431 is provided on the upstream side of the water supply pipe 10. A water supply valve (hereinafter referred to as “electromagnetic valve” for convenience of explanation) 431 is an openable / closable electromagnetic valve, and is supplied to the heat exchanger 440 based on a command from the control unit 405 provided in the casing 400. Control the water supply.

  A water entry thermistor 432 is provided on the downstream side of the electromagnetic valve 431. The incoming water thermistor 432 detects the temperature of the water led to the heat exchanger 440. An instantaneous heating type heat exchanger 440 is provided downstream of the incoming water thermistor 432. The heat exchanger 440 detects the temperature of the water heated by the heater pattern 441, the auxiliary flow path opening / closing valve 442, and the heater pattern 441 that instantaneously heats the supplied water to make the water warm to a predetermined temperature. And a hot water thermistor (water temperature detection means) 443 that outputs the above information to the control unit 405.

  The energization control of the heater pattern 441 for heating the water supplied to the heat exchanger 440 to a predetermined temperature is performed by the temperature of water entering the heat exchanger 440 detected by the water-filling thermistor 432 and the hot water thermistor 443. The control unit 405 captures information on the detected temperature of the heated water, and is performed in a combination of feedforward control and feedback control.

  In addition, the heat exchanger 440 detects the presence or absence of water stored in the heat exchanger 440, and the float switch 444 that prevents emptying of the heat exchanger 440 and the temperature of water flowing out of the heat exchanger 440 are safe. A limiter thermistor (water temperature detecting means) 445 for confirming this, and a vacuum breaker 446 for preventing sewage from flowing backward from the cleaning nozzle 471 when a negative pressure is generated on the electromagnetic valve 431 side, for example.

  Here, the downstream of the water supply pipe 10 branches in two directions at the auxiliary flow path opening / closing valve 442. One flow path is the main flow path 11 for supplying water heated by the heater pattern 441 to the cleaning nozzle 471, and the other flow path is for supplying water heated by the heater pattern 441 to the nozzle cleaning chamber 472 (see FIG. 9). ) And the secondary flow path 12 for discharging into the bowl 801 of the toilet bowl 800. That is, the auxiliary flow path opening / closing valve 442 and the auxiliary flow path 12 are provided between the heater pattern 441 and the hot water thermistor 443. Then, the control unit 405 controls and opens the sub-channel opening / closing valve 442 to pass water heated by the heater pattern 441 to the sub-channel 12, and in the nozzle cleaning chamber 472 and the bowl 801 of the toilet bowl 800. Can be discharged.

  Downstream of the heat exchanger 440, a flow path switching / flow rate adjusting valve 450 for opening / closing and switching water supply to the cleaning nozzle 471 and the nozzle cleaning chamber 472 (see FIG. 9) and adjusting the water flow (flow rate) is provided. Yes. The downstream of the flow path switching / flow rate adjusting valve 450 branches, for example, in four directions. One channel is the waste water channel 15, and the remaining channel is the nozzle channel 14 that supplies the water supplied from the heat exchanger 440 to the cleaning nozzle 471. The number of nozzle channels 14 installed can be appropriately changed according to the number of nozzles 473 installed in the cleaning nozzle 471. Further, a nozzle device 470 having a cleaning nozzle 471 is provided downstream of the flow path switching / flow rate adjusting valve 450.

  In this embodiment, the hot water thermistor 443 and the limiter thermistor 445 are installed in the heat exchanger 440, but the installation form of the hot water thermistor 443 and the limiter thermistor 445 is not limited to this. That is, the hot water thermistor 443 and the limiter thermistor 445 need not be installed in the heat exchanger 440 as long as they are arranged in the main flow path 11.

  FIG. 9 is a block diagram illustrating a specific example of the main configuration of the water channel system of the human body cleaning apparatus according to this embodiment.

  As shown in FIG. 9, water supplied from a water supply source (not shown) is first guided to the branch fitting 410. The water guided to the branch fitting 410 is distributed to the connecting hose 420 and a valve unit for toilet flushing (not shown). However, the toilet apparatus provided with the human body cleaning apparatus 401 according to the present embodiment is not limited to the so-called “water direct pressure type”, and may be a so-called “low tank type”. Therefore, when the toilet device is a “low tank type”, the water guided to the branch fitting 410 is guided to a low tank (not shown) instead of the valve unit for toilet flushing.

  Subsequently, the water supplied to the connection hose 420 is guided to the valve unit 430. The valve unit 430 includes an electromagnetic valve 431, a water inlet thermistor 432, a water drain plug 433, a pressure regulating valve 434, and a check valve 435. The water drain plug 433 is used when the water in the water supply pipe 10 may freeze, and can discharge the water in the water supply pipe 10. Further, the pressure regulating valve 434 has a role of adjusting to a predetermined pressure range when the feed water pressure is high. The electromagnetic valve 431 and the incoming water thermistor 432 are as described above with reference to FIG.

Subsequently, the water supplied to the valve unit 430 is guided to the heat exchanger 440. The heat exchanger 440 includes a heater pattern 441, a sub-channel opening / closing valve 442, a hot water thermistor 443, a float switch 444, a limiter thermistor 445, and a vacuum breaker 446. The water supplied into the heat exchanger 440 is instantaneously heated by the heater pattern 441 while flowing through the flow path 448a.
Note that the heater pattern 441, the sub-channel opening / closing valve 442, the hot water thermistor 443, the float switch 444, the limiter thermistor 445, and the vacuum breaker 446 are as described above with reference to FIG.

  The water heated in the heat exchanger 440 is guided to the channel switching / flow rate adjusting valve 450 through the main channel 11. The water guided to the flow path switching / flow rate adjusting valve 450 is switched between water flow to the cleaning nozzle 471 side and water flow to the nozzle cleaning chamber 472 side, and the water pressure is adjusted. The nozzle cleaning chamber 472 included in the nozzle device 470 can clean the outer peripheral surface (body) of the cleaning nozzle 471 by spraying water from a water discharge unit (not shown) provided in the nozzle device 470.

  Subsequently, the water passed from the flow path switching / flow rate adjusting valve 450 to the cleaning nozzle 471 side is supplied to the pressure modulation device 460. The pressure modulation device 460 can pulsate the flow of water in the main flow path 11 and pulsate the water discharged from the water discharge port 473 of the cleaning nozzle 471. Subsequently, the water supplied from the pressure modulation device 460 to the nozzle device 470 is supplied to each nozzle flow path 14 corresponding to, for example, “wet washing”, “soft washing”, “bidet washing”, and the like by the flow path switching valve 475. (See FIG. 8). Then, the water passed through the nozzle channel 14 is jetted from the respective water outlets 473 corresponding to, for example, “wet washing”, “soft washing”, “bidet washing”, and the like to the local body part. On the other hand, the water passed from the flow path switching / flow control valve 450 to the nozzle cleaning chamber 472 side is directed to the outer peripheral surface (body) of the cleaning nozzle 471 from a water discharge portion (not shown) provided in the nozzle cleaning chamber 472. Is injected.

  According to human body cleaning apparatus 401 according to the present embodiment, water can be instantaneously heated by heat exchanger 440 without heating unevenness, and desired cleaning water can be jetted from cleaning nozzle 471 immediately after passing water. It becomes like this.

Next, control of energization to the plurality of heater patterns 441a, 441b, and 441c will be described.
As shown in FIG. 8, the control unit 405 controls energization to the plurality of heater patterns 441a, 441b, and 441c of the heat exchanger 440 to adjust the heating temperature of the water flowing through the flow path 448a.
The control unit 405 controls energization to the plurality of heater patterns 441a, 441b, and 441c by, for example, PWM (Pulse Width Modulation).

  The control unit 405 controls ON / OFF of energization by dividing one set into a plurality of waves (for example, 16 waves) for one of the heater patterns 441a, 441b, and 441c. A plurality of sets (for example, 4 sets) is set as a control unit.

  The control unit 405 controls the ON / OFF of energization for each of the plurality of heater patterns 441a, 441b, and 441c in units of one wave, so that an output corresponding to the ratio of the energization time in the control unit can be obtained.

  In the heat exchanger 440 according to the present embodiment, in such energization control by the control unit 405, the energization time to each of the plurality of heater patterns 441a, 441b, and 441c is controlled to be equal.

  For example, when only one of the plurality of heater patterns 441a, 441b, and 441c is used to obtain a desired output, the plurality of heater patterns 441a, 441b, and 441c are used in order. As a result, it is not biased to use only in one system, and it is possible to suppress the deterioration of only a specific heater pattern. Therefore, the lifetime of the entire heat exchanger 440 can be extended.

10-12 is a figure explaining the specific example of control. In each figure, (a) illustrates the energization state to the heater pattern 441a, (b) illustrates the energization state to the heater pattern 441b, and (c) illustrates the energization state to the heater pattern 441c. .
In this control example, one control unit is four sets, and energization control is performed with 16 waves per set. The output of each of the plurality of heater patterns 441a, 441b, and 441c is 400W.

The specific examples shown in FIGS. 10 to 12 show the energized state when an output of 25 W is obtained in one control unit. Here, in order to obtain an output of 25 W, energization for four waves may be performed within one set for one of the three heater patterns 441a, 441b, and 441c. That is, for one heater pattern, a 400 W output is energized in 4 out of 16 waves in one set, that is, 4/16. This gives a 4/16 100W output of 400W per set. Further, the other two heater patterns are not energized.
Furthermore, among the four sets of one control unit, the other three sets are not energized to any of the heater patterns 441a, 441b, and 441c. That is, 0 W.
Therefore, in one control unit, only one set out of the four sets has an output of 100 W, so an output of 25 W, which is 1/4 of 100 W, can be obtained.

  In FIG. 10, 4/16 waves are energized to obtain 100 W only for the first set set1 of the heater pattern 441a among the three heater patterns 441a, 441b and 441c in one control unit. On the other hand, the other two heater patterns 441b and 441c are not energized in any set.

As in this specific example, when the 25 W output is continued, if only the same heater pattern 441a is always energized, the deterioration of the heater pattern 441a is more likely to proceed than the other two heater patterns 441b and 441c.
Therefore, in the present embodiment, the three heater patterns 441a, 441b, and 441c are energized in order under the control of the control unit 405 so that the energization times are equalized.

For example, in this specific example, as shown in FIG. 10, only the first set set1 of the heater pattern 441a is energized to obtain 100 W for one control unit, and the next one control unit is shown in FIG. As described above, only the first set set1 of the heater pattern 441b is energized to obtain 100W.
Furthermore, in the next one control unit, as shown in FIG. 12, only the first set set1 of the heater pattern 441c is energized to obtain 100 W.
In this way, the heater patterns to be energized are switched in order so that the heater patterns 441a, 441b, and 441c are energized equally.

Thereby, the plurality of heater patterns 441a, 441b, and 441c are not used in a biased manner, and the life of the entire heat exchanger 440 can be extended.
Note that switching of energization targets is not limited to one control unit. For example, the heater pattern to be energized may be switched for each seating or every time energization becomes zero. In other words, the energization time to the plurality of heater patterns 441a, 441b, and 441c may be switched over in a predetermined use period.

The embodiment of the present invention has been described above. However, the present invention is not limited to these descriptions. As long as the features of the present invention are provided, those skilled in the art appropriately modified the design of the above-described embodiments are also included in the scope of the present invention. For example, the number, pattern shape, material, arrangement, and the like of the heater patterns 441 included in the heat exchanger 440 are not limited to those illustrated, and can be changed as appropriate.
Moreover, each element with which each embodiment mentioned above is provided can be combined as long as technically possible, and the combination of these is also included in the scope of the present invention as long as it includes the features of the present invention.

  DESCRIPTION OF SYMBOLS 10 Water supply piping, 11 Main flow path, 12 Sub flow path, 14 Nozzle flow path, 15 Waste water flow path, 100 Sanitary washing device, 200 Toilet seat, 300 Toilet lid, 400 Casing, 401 Human body washing device, 404 Seating detection sensor, 405 Control Part, 410 branch fitting, 420 connection hose, 430 valve unit, 431 water supply valve (solenoid valve), 432 water thermistor, 433 water stopper, 434 pressure regulating valve, 435 check valve, 440 heat exchanger, 441 heater pattern, 442 sub Channel open / close valve, 443 Hot water thermistor, 444 Float switch, 445 Limiter thermistor, 446 Vacuum breaker, 450 , 475 channel switching valve, 800 toilet, 801 bowl

Claims (4)

A ceramic heating element having a cylindrical part provided with a plurality of heater patterns, and a water flow path in which the cylindrical part of the heating element is inserted and heated through the inside of the cylindrical part of the heating element A heat exchanger having a case part formed around the cylindrical part,
A cleaning nozzle for discharging water heated by the heat exchanger;
There line control of protraction of the control and the cleaning nozzle of the heating of the heating element by one or more by energizing a combination of heater pattern, of the plurality of heater pattern, each of the plurality of heater pattern About, it is possible to obtain an output according to the ratio of energization time, and when energizing only one of the plurality of heater patterns, a control unit that sequentially uses the plurality of heater patterns ;
A human body cleaning device comprising:
The plurality of heater patterns are repeated in parallel with each other along the peripheral side surface of the cylindrical portion and folded back in the extending direction of the cylindrical portion,
Each of the plurality of heater patterns is provided without intersecting with other heater patterns without overlapping itself,
The flow path is configured to flow the water in a direction intersecting with the direction of folding of each of the plurality of heater patterns, and to flow the water spirally around a central axis of the cylindrical portion. human body washing apparatus characterized by having the inner wall formed in a spiral groove of the case portion.   The human body cleaning apparatus according to claim 1, wherein outputs of the plurality of heater patterns of the heat exchanger are uniform.   3. The human body cleaning apparatus according to claim 1, wherein one end of each of the plurality of heater patterns of the heat exchanger is connected to one common electrode.   The human body cleaning apparatus according to claim 1, wherein the control unit controls the energization time to each of the plurality of heater patterns to be equal.

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