FR2974285A1 - SHOWER - Google Patents

Abstract

The invention relates to a wad (2) comprising: - a tank of clean water (76) for storing clean water therein; - a shower head (20) fluidically connected to the tank of clean water (76), - a heating element (96) for heating the clean water transmitted to the knob (20) around a set temperature, - at least one hot water pipe connected between the tank (76) of clean water and the shower head (20) for conveying to the knob the water heated by the heating element, the knob (20) being only fluidly connected to this tank of clean water (76) via of said at least one hot water pipe.

Description

SHOWER

[1] The invention relates to a shower. [2] A constantly rising water price, combined with ever more stringent environmental standards, has led sanitaryware builders to develop showers with low water consumption. [3] For this purpose, it has already been proposed to perform showers operating in a closed circuit. By "closed-circuit shower" is meant a shower for which gray water from the shower is collected and treated for the purpose of reuse for the same purpose. [4] Typically, showers operating in closed circuit include: - a tank of clean water for storing clean water therein, - a shower head fluidically connected to the tank of clean water, 15 -a shower tray adapted to collect greywater from the shower head, after their use for washing, - a tangential filtration module comprising porous walls for filtering the greywater collected by the shower tray, this module comprising an inlet of greywater, a gray water outlet and a clean water outlet, -a greywater pipe connecting the gray water inlet of the filtration module to the shower tray, - a clean water pipe fluidly connecting the clean water outlet of the filtration module to the clean water tank, - at least one pump capable of circulating the greywater through the filtration module, - a heating element for heating the water clean transmitted to the pommel around a set temperature, - at least one hot water pipe connected between the clean water tank and the shower head to convey to the knob the water heated by the heating element 30. [12] A shower operating in closed circuit is suggested in the patent application FR2899576. [13] It is also desirable that these showers operating in a closed circuit are easily transportable. Indeed, they could then be used in nomadic applications such as tents. However, for this, it is necessary to greatly reduce their weight and their size. [14] For example, all shower piping should be kept to a minimum. [15] It is also necessary to reduce the size of the filtration system. For example, in the above-mentioned document, in order to make the collected greywater suitable for reuse, the shower comprises an ultrafiltration module, a bacterial treatment module, a particulate filter, and an electronic module. flocculation. These modules occupy a significant space that it is desirable to reduce. In addition, the porous walls of the tangential filtration module clog up quickly (clogging of their pores with particles of diameter greater than the hydraulic diameter of these pores). Also, it is necessary to regularly change this filtration module which represents a cost for the user. Finally, the safety of a shower closed circuit must be improved. The invention aims to solve one or more of the above disadvantages. The invention relates to a shower in which the pommel is only fluidly connected to the tank of clean water through said at least one hot water pipe. In the shower above, it is no longer necessary to have: - a hot water tank and a cold water tank, - a mixer in the shower, and - hot water pipes and cold water connected between the mixer and, respectively, the hot and cold water tanks. Thus, the connection of the shower head to the tank of clean water only by the hot water pipe can substantially reduce the size of the shower. The embodiments of this shower may include one or more of the following features: said at least one pump is adapted to circulate the greywater through the filtration module with a flow rate sufficient to obtain a flow of water clean output of this module equal to the flow of clean water from the pommel to 10%; the hydraulic diameter of the pores of the porous walls of the filtration module is less than 30 nm, and said at least one pump and the pipes are arranged in such a way that the transmembrane pressure between the greywater inlet and the outlet of greywater is less than or equal to 0.3 bar, when the flow of greywater circulating in the greywater pipe is between 150 liters per hour and 500 liters per hour; the hydraulic diameter of the pores of the filtration module is greater than 8 nm; said at least one pump and the pipes are arranged in such a way that the transmembrane pressure between the greywater inlet and the greywater outlet is greater than or equal to 0.1 bar, when the flow of water gray circulating in the gray water pipeline is between 150Litres per hour and 500Litres per hour ^ the shower comprises: - a conductivity sensor of clean water, - a water indicator unfit for use, and - a unit control unit programmed to trigger display by the indicator of an improper water indication, when a measurement of the conductivity sensor crosses a predetermined threshold; the shower comprises a cabin, this cabin comprising: a waterproof fabric, and folding arches supporting the fabric, the structure of the arches being such that the cabin has a flared shape, the width of the cabin at the base, at the shower tray, being less than the width of the cabin one meter above the shower tray; the shower comprises: a controllable valve, movable between an open position in which the valve allows the flow of clean water from the clean water tank to the knob and a closed position in which the valve prohibits the flow; clean water from the clean water tank to the pommel, and - a remote control, watertight, able to control the movement of the valve between its open and closed positions; the shower comprises a photovoltaic panel and an electrically connected battery to this panel so as to render the shower self-sufficient in electrical energy; This shower has a chest, equipped with wheels for easy transport, inside which are housed the clean water tank, the tangential filtration module, the clean water pipe connected to the clean water outlet of the filtration module 25 and the tank of clean water, and the greywater pipe connected to the greywater inlet. Embodiments of this invention also have the following advantages: when the flow of clean water at the outlet of the filtration module is equal to the flow of clean water coming from the pommel to within 10%, it is possible to reduce the size of the tank of clean water and by the same to reduce the size of the shower, - when the hydraulic diameter of the pores of the porous walls of the filtration module is less than 30nm the filtration module is suitable for filter more than 90% of viruses that may be in greywater. It is then possible to remove the electro-flocculation module and thereby reduce the bulk of the shower; by limiting itself to a transmembrane pressure of less than 0.3 bar, the risk of clogging the pores of the porous walls by particles whose diameter is greater than 30 nm is considerably limited. Thus, it is possible to extend the life of the tangential filtration module; when the hydraulic diameter of the pores of the filtration module is greater than 8 nm, it is avoided that ions contained in greywater block the pores of the porous walls by binding to these pores, when the transmembrane pressure is greater than 0, 1 bar, the flow of gray water through the porous walls to reach the tank of clean water is large enough to allow the closed circuit operation of the shower without adding additional pump in the clean water pipe, - when the shower includes a conductivity sensor and an indicator, it is possible to warn a user that the treated water is unfit for reuse when the conductivity of clean water exceeds a predetermined threshold, - when the shower head is only fluidly connected to the tank of clean water containing a heating element, we can limit the size of the shower by equipping it with a single cuv e of clean water, - when the controllable valve is attached to the shower tray and controlled by the remote control, the weight supported by the shower enclosure is limited, - when the structure of the cabin is flared, the volume occupied by the shower is limited. the cabin at the shower tray, which allows for a space-saving tray while maintaining a cabin volume allowing the user to move the upper body without discomfort, and 20 - when the shower comprises a trunk, the transport of this shower is facilitated. Other features and advantages of the invention will emerge clearly from the description which is given below, for information only and in no way limitative, with reference to the accompanying drawings, in which: - Figure 1 is a schematic illustration 2a is a schematic illustration of a tangential filtration module of the shower of FIG. 1; FIG. 2b is a schematic illustration of a duct of the filtration module of FIG. 2a; Figure 3 is a flowchart of a shower operation method of Figure 1. [0018] In these figures the same references are used to designate the same elements. In the following description, the features and functions well known to those skilled in the art are not described in detail. [0020] Figure 1 illustrates a shower 2. This shower 2 comprises: - a shower cabin 4, - a shower tray 6, and - a trunk 8 for greywater treatment. The cabin 4 is removable. This cabin 4 is formed of a web 40 impermeable to water, and arches 12 supporting this fabric 10. In the example, the shape of the arches 12 is such that the cabin 4 has a flared shape. By "flared shape" is meant the characteristic that the width of the cabin 4 at its base, at the tray 6, is less than the width of the cabin 4 at one meter above the tray 6. For example, here , the difference in width is greater than 10 or 20cm. The canvas 10 closes in the upper part of the cabin to form a roof. The arches 12 are foldable. For this purpose, here the arches 12 are formed of rods mechanically connected to each other by means of sleeves. For example, the arches 12 are made of aluminum. Here, the cabin comprises two arches intersecting at the top of the cabin 4. [0023] The fabric 10 is preferably treated with a water repellent coating. Under these conditions, the fabric 10 promotes the flow of greywater to the shower tray 6. Moreover, such a treatment can slow the development of possible mold on the canvas 10. The canvas 10 includes an opening 14 forming an entry door for the cabin 4. This opening 14 advantageously comprises a watertight closure mechanism. Here, this mechanism is a zipper. Preferably, the zipper is also treated with an anti-water repellent coating. The fabric 10 comprises a sleeve 16 inside which is received a pipe 18 for supplying clean water. In the example, the sleeve 16 extends from a lower part of the cabin to the top of this cabin 4. The pipe 18 opens on a shower head 20 on the one hand and on a hydraulic interface 22 of the tray 6 of 'somewhere else. The shower enclosure 4 finally includes a support 24 to be able to hang and alternately unhook a remote control 26. For example, the support 24 is a vertical rod attached to its lower end on the tray 6. [0027] The remote control 26 is waterproof. This remote control 26 comprises: - a wireless transmitter 28 for transmitting commands to a receiver 30, and - buttons 32, 34 for, respectively, adjusting the temperature of the clean water from the shower head, and controlling a water supply own pommel. The shower tray 6 comprises: - a bowl 40 for collecting greywater and to support the weight of the person who takes his shower, this bowl 40 opening on a neck 42, - a pipe 44 fluidly connecting the neck 42 a gray water outlet interface 46, - a non-slip mat 48, disposed at the bottom of the bowl 40 ,, - a filter 49 disposed under the non-slip mat 48 in the neck 42 to retain large contained bodies in greywater such as hair, - the receiver 30, and - a controllable electro-valve 36. In the example the base of the cabin 4 is placed on the bowl 40. In the example, the filter 49 is shaped so as to retain at least 90% of the possible bodies contained in the greywater of which the diameter is greater than or equal to 40 μm and, preferably, to 30 μm or 24 μm. For this purpose, the filter 49 is formed of meshes whose hydraulic diameter is less than 40 μm and, preferably, less than 30 or 24 μm. For example, the filter 49 is a nonwoven filter. In this description, the term "nonwoven filter" refers to a filter made from a nonwoven fabric. In this description, the "hydraulic diameter" of a passage section is defined by the following relation: Dh = 4. A / P, where - Dh, is the hydraulic diameter of the section of passage,

- A, is the area of the passage section, and - P, is the wet perimeter of the passage section. The solenoid valve 36 is fluidly connected to the hydraulic interface 22 and to a hydraulic interface 53 via a pipe 50. The solenoid valve 36 is able to be displaced in response to a pressure on the button 34, between: - an open position in which the pipe 50 is completely closed, and - a closed position in which the pipe 50 is at least partly unclosed and vice versa. The receiver 30 and the solenoid valve 36 are electrically connected to an electrical interface 52. In order to simplify FIG. 1, the electrical connections 30 are not shown. The trunk 8 comprises: hydraulic interfaces 60 and 62 intended to be fluidly connected to the interfaces, respectively, 46 and 53, and an electrical interface 63 intended to be electrically connected to the interface 52. [0035] The trunk 8 also comprises a greywater treatment line comprising: a biological reactor 70 in which the gray water coming from the tank 6 is received and a bacterial complex for degrading organic matter contained in these greywater; modules 72 tangential filtration gray water from the reactor 70, - an activated carbon filter 74, - a tank of clean water 76, and - an ultraviolet sterilizer 78. [0036] The processing chain also comprises: a pump 71 for sucking the greywater collected by the tank 6 to the reactor 70, - a pump 73 for extracting the greywater from the reactor 70 and driving the latter through the modules 72, and - a pump 81 for r bring the clean water of the tank 76, to the interface 62 through the sterilizer 78. The reactor 70 is fluidly connected to the interface 60 and the modules 72. Here, the bacterial complex received within Reactor 70 comprises, for example, the following bacteria: - Micrococcus, - Pseudomonas, - Nitrosomas, - Nitrobacter, - Bacillus subtilis. Preferably, the bacterial complex is composed more than 50% or 80% by weight by these bacteria. The reactor 70 comprises an aerator (not shown) disposed at the bottom of the reactor 70 to oxygenate greywater and allow the degradation of organic material in an aerobic environment. The reactor 70 is known per se. Also, this one is not described in more detail. The tangential filtration modules 72 filter the greywater contained in the reactor 70 so as to obtain a permeate and a concentrate. By "permeate" is meant the product of the filtration of the module 72 freed of particles of diameter greater than 30 nm. The term "concentrate" refers to the filtration residues of the module 18 having particles of diameter greater than 30 nm. In order to increase the flow of greywater filtered tangentially, the modules 72 are arranged in parallel. Here, the number of modules 72 is greater than or equal to two, four or six. In order to simplify the figures, only one module 72 is illustrated in FIG. 1. Each module 72 comprises: an inlet 79 fluidically connected to the reactor 70 via a pipe 80, an outlet 85 fluidically connected to the activated carbon filter 74 through a pipe 82, through which the permeate is expelled out of the module 72 to the filter 74, and - an outlet 83 fluidly connected to the reactor 70 through a pipe 84, through which the concentrate is expelled out of the module 72 and back into the reactor 70. The pump 73 is fluidly connected to the pipe 80. In order to limit the clogging of the pores of the modules 72, the pump 73 and the pipes 80, 82 are arranged with in such a way that the transmembrane pressure between the inlet 79 and the outlet 83 is less than or equal to 0.3 bar, when the flow of greywater circulating in the pipe 80 is between 150 liters per hour and t 500Litres per hour. Transmembrane pressure is the pressure difference between greywater upstream and downstream of the filter. In addition, in order to maintain a sufficient flow of permeate extracted greywater by each of the modules 72, the pump 73 and the pipes 80, 82 are arranged in such a way that the transmembrane pressure between the inlet 79 and the outlet 83 is greater than or equal to 0.1 bar, and preferably greater than 0.15 bar, when the flow of greywater flowing in the pipe 80 is between 150 liters per hour and 500 liters per hour. To achieve the desired transmembrane pressure, the flow in the pipe 80 is set between 150 liters per hour and 500 liters per hour. Then, the section of the lines 80 and 84 is experimentally varied until the transmembrane pressure is between 0.1 bar and 0.3 bar. A module 72 is described in detail below with reference to Figures 3a and 3b. The activated carbon filter 74 filters the permeate from the modules 72 and reverse the result of this filtration in the tank 76. More particularly the filter 74 is able to: - eliminate any odors emanating from the filtered permeate, and - eliminate any pesticides contained in greywater. The pesticides treated here are typically those found regularly in anti-dandruff shampoo. In the example, the volume capacity of the tank 76 is equal to the volume capacity of the reactor 70 at plus or minus 25%. For example, the volume capacity of the tank 76 is less than 20 or 50 liters. Here, the capacity of the tank 76 is between 10 and 50 liters. The sterilizer 78 destroys any bacteria developed within 40 of the tank 76. For this purpose, the sterilizer 78 comprises an ultraviolet lamp projecting a light beam on clean water at the outlet of the tank 76. Typically, the wavelengths of the light beam are between 200 nm and 280 nm. For example, the wavelength is equal to or close to 250 nm. The sterilizer 78 is housed inside a pipe 90 fluidly connecting the tank 76 to the interface 62. The pump 81 is fluidly connected to the pipe 90. Here, the pump 81 is disposed downstream of the sterilizer 78. [0052] The box 8 furthermore comprises: - a sensor 92 for the conductivity of clean water in the tank 76, 10 - an indicator light 94 for indicating that the clean water in the tank 76 is unsuitable for the use, - a heating element 96, such as a heating resistor, for heating clean water in the tank 76, - photovoltaic panels 98 for producing electricity from solar energy, and at least a battery 100 for storing the electricity produced by the photovoltaic panels, and a control unit 102. The interface 63, the sensor 92, the heating element 96, and the battery 100 are electrically connected to the control unit 102. [0054] In the example, the unit 102 is implemented using a programmable electronic computer capable of executing instructions recorded on an information recording medium. For this purpose, the unit 102 is connected to a memory 104 containing instructions for carrying out the method of FIG. 3. The box 8 also comprises wheels 105 to facilitate the transport of this box 8. A tangential filtration module 72 will now be described in detail with reference to Figures 2a and 2b. A module 72 is formed of a plurality of parallel ducts 110 between them, within which circulate greywater 112 from the reactor 70. In order to simplify Figure 2a, only two ducts are illustrated. A conduit is more visible in Figure 2b. The ducts 110 comprise porous walls 114 so that when the greywater 112 circulates inside the ducts 110, a permeate 116 passes through the walls 82 to reach the outlet 85. The liquid that has not Without crossing the walls 82 forms with the impurities it contains the concentrate 118 which joins the outlet 83. Preferably, the ducts 110 are cylindrical. Here, the section of the ducts 110 is circular. In the example, the hydraulic diameter of the ducts 110 is less than or equal to 250 μm and preferably less than 220 μm. Here, the hydraulic diameter of the ducts 110 is 210pm. Still in the example, the hydraulic diameter of the pores of the porous walls 114 is less than 30 nm, and preferably less than 20 nm. Moreover, the hydraulic diameter of the pores is preferably greater than 8 nm. Here, the pore diameter is 20 nm. A method of operation of the shower 2 will now be described with reference to Figure 3. In a preliminary phase 200, the shower 2 is put into service. For this purpose, during a step 202 the user fluidly connects the hydraulic interfaces 46 and 53 of the tray 6, respectively, to the hydraulic interfaces 60 and 62 of the trunk 8, via pipes. Under these conditions, the assembly constituted by the pipe 44 and the pipe fluidly connecting the interfaces 46 and 60 forms a greywater pipe.

The pipe 82 forms a clean water pipe. Here, the clean water tank is connected to the knob 20 only by a single pipe. In a step 204, the user electrically connects the electrical interfaces 52 and 63, via a cable. In a step 208, the bacterial complex is supplied to the reactor 70. For example, the user pours the bacterial complex and a volume of water into the bowl 40. Then, in response to a user command. , the pump 71 is actuated so as to drive the bacterial complex and the volume of water in the reactor 70. Finally, during a step 209, the user fills the tank 40 with greywater, for example, from a river, then actuates the pump 71. The gray water is then introduced into the reactor 70 where they are treated bacteriologically. Then, the pump 73 is put into service to pump the water from the reactor 70 to the modules 72 and the activated carbon filter 74. Under these conditions, the tank 76 fills gradually in clean water from gray water discharged into the Tray 40. During a phase 210, a user uses the shower 2. During a step 212, the user turns on the unit 102. [0069] During a step 214 , Unit 102 verifies that the water stored in the tank 76 are fit for their use. For this purpose, the unit 102 acquires a measurement of the sensor 92. Then the unit 102 compares this measurement with a predetermined conductivity threshold. In this step 214, if the measurement acquired by the unit 102 is greater than the predetermined threshold, the unit 102 turns on the indicator light 94 indicating to the user that the water of the tank 76 is unsuitable for its operation. use. Indeed, a measured conductivity greater than the predetermined threshold results from an excessive amount of salts contained in the waters of the tank 76. In this case, the user is invited to change the water of the tank 76 and the process is interrupted. On the other hand, if the measurement acquired by the unit 102 is less than the predetermined threshold, the unit 102 does not turn on the indicator light 94 and the process continues. In a step 216, the user presses the button 34 so as to actuate a supply of clean water to the knob 20. The transmitter 28 of the remote control 26 then transmits a water supply control to the computer 102 through the receiver 30 and the cable connecting the interfaces 52, 63. In a step 218, in response to the receipt of this command, the unit 102 actuates the opening of the electro -vanne 36 so as to allow the supply of clean water from the tank 76 to the knob 20. The pressure then decreases in the pipe at the outlet of the pump 81. This pressure drop is detected by a pressure sensor connected to Unit 102 then controls the operation of pumps 81 and 71. Pump 73 starts automatically when a minimum water level is reached in vessel 70. [0074] In addition to execution of step 216, during a step 220 the user presses the button 32 so as to adjust a The remote water temperature transmitter 26 is then transmitted to the control unit 20. The transmitter 28 of the remote control 26 then transmits a control of adjustment of the temperature setpoint to the unit 102 via the receiver 30. in a step 222, in response to receiving this command, the unit 102 controls the heating element 96 to regulate the temperature around the user-adjusted setpoint. [0076] The user then takes a shower. While he is taking a shower, the greywater resulting from his washing is collected by the tank 6 and then taken to the reactor 70 under the action of the pump 71. The organic materials contained in the greywater are treated bacteriologically with the water. The pump 73 conducts gray water from the reactor through the filtration module 72 and then through the filter 74 to clean the gray water. The water made clean by the reactor 70, the modules 72, and the sterilizer 78 is stored in the tank 76. The pump 81 conducts the clean water from the tank 76 to the knob 20. Thus, the shower operates in a closed circuit . [0077] Advantageously, the pumps 71, 73, and 81 are controlled by the unit 102 so as to circulate the greywater through the filtration module 72 with a flow rate sufficient to obtain a flow of clean water at the outlet of this module 72 equal to the flow of clean water from the pommel to 10%. Under these conditions, the volume capacity of the tank 76 is low. After having taken a shower, during a step 224, the user presses the button 34 so as to cut off the supply of clean water to the knob 20. [0079] In response to this command, when In a step 226, the solenoid valve 36 is closed. The pressure in the pipe at the outlet of the pump 81 increases. When this pressure reaches a predetermined threshold, the unit 102 controls the stopping of the pumps 71, 73 and 81. 10 users to use shampoos containing pesticides. The sterilizer 78 and the panels 98 may also be omitted. The indicator light may be replaced by a screen or a sound signal generator or may be omitted. The filter 49 is not necessarily nonwoven. The filter 49 may be any type of filter capable of performing the same function as the filter 49. [0087] The pumps and the pipes may be arranged in such a way that the transmembrane pressure between the inlet and the outlet of water gray is greater than or equal to 0.3 bar, when the flow of greywater flowing in the greywater pipe is between 150 liters per hour and 500 liters per hour. The heating element 96 is not necessarily disposed inside the tank 76. It can also be placed outside this tank. For example, a pump placed in the tank circulates the clean water to the outer heating element and then returns the heated water to the tank 76. In another embodiment, the heating element is placed in the tank. ducting which connects the tank 76 to the knob 20. Alternatively, the step 214 may be repeated during a shower to verify whether during the shower water stored in the tank are always fit for their use. [0090] Different characteristics disclosed in the present application can be implemented in the shower 2 independently of the implementation of the tangential filtration module 72. The use of the conductivity sensor and the indicator can be implemented independently of the use of a tangential filtration module as described. The use of a hose hydraulically connecting the pommel only to the tank of clean water and a heating element as described can be implemented independently of the use of a tangential filtration module of which the pore size is less than 30 nm and arranged so that the transmembrane pressure is less than 0.3 bar. [0080] Many other embodiments are possible. The cabin 2 can be used independently of the use of the tray 6 and the trunk 8. The activated carbon filter 74 can be omitted, for example if it is forbidden

Claims (10)

REVENDICATIONS1. Shower (2) comprising: - a clean water tank (76) for storing clean water therein; - a shower head (20) fluidically connected to the clean water tank (76); a shower tray (6) adapted to collect greywater from the pommel (20), after being used for washing, - at least one tangential filtration module (72) comprising porous walls for filtering the greywater collected by the shower pan (6), this module (72) having a gray water inlet (79) and a clean water outlet (85), - a greywater pipe (80) fluidly connecting the water inlet greywater (79) from the filtration module (72) to the shower pan (6), - a clean water pipe (82) fluidly connecting the clean water outlet (85) of the filtration module (72) to the clean water tank (76), and - at least one pump (73) adapted to circulate the greywater through the filtration module (72), - a heating element (96) for heating the clean water transmitted to the pommel (20) around a set temperature, - at least one hot water pipe connected between the tank (76) of clean water 20 and the shower head (20) for conveying up to in the knob the water heated by the heating element, characterized in that the knob (20) is only fluidly connected to this tank of clean water (76) via said at least one hot water pipe . 25 2. Shower according to claim 1, wherein said at least one pump (71, 73, 81) is adapted to circulate the greywater through the filtration module (72) with a flow rate sufficient to obtain a flow of water clean output of this module (72) equal to the flow of clean water from the knob (20) to 10%. 30 Shower according to any one of the preceding claims, in which: the hydraulic diameter of the pores of the porous walls of the filtration module (72) is less than 30 nm, and the said at least one pump (71, 73, 81). and the pipes (80, 82) are arranged in such a way that the transmembrane pressure between the greywater inlet (79) and the greywater outlet (83) is less than or equal to 0.3 bar, when the flow of greywater circulating in the greywater pipe (80) is between 150 liters per hour and 500 liters per hour. 4. Shower according to claim 3, wherein the hydraulic diameter of the pores of the filtration module (72) is greater than 8 nm. Shower according to any one of the preceding claims, wherein said at least one pump (71, 73, 81) and the pipes (80, 82) are arranged in such a way that the transmembrane pressure enters the inlet of greywater (79) and greywater outlet (83) is greater than or equal to 0,1 bar, when the flow of greywater circulating in the greywater pipe (80) is between 150 liters per hour and 500 liters per hour. Shower according to any one of the preceding claims, wherein the shower (2) comprises: - a conductivity sensor (92) of clean water, - a water indicator (94) unfit for use, and - A control unit (102) programmed to trigger the display by the indicator (94) of an improper water indication, when a measurement of the conductivity sensor (92) exceeds a predetermined threshold. 7. Shower according to any one of the preceding claims, wherein the shower (2) comprises a cabin (4), this cabin comprising: - a fabric (10) impermeable to water, and - foldable hoops (12) supporting the fabric (10), the structure of the arches (12) being such that the car (4) has a flared shape, the width of the car (4) at the base, at the shower tray (6), being less than the width of the cabin (4) one meter above the shower tray (6). 8. Shower according to any one of the preceding claims, wherein the shower (2) comprises: - a valve (36) controllable, movable between an open position in which the valve allows the flow of clean water from the tank of clean water (76) to the pommel (20) and a closed position in which the valve prevents the flow of clean water from the clean water tank (76) to the pommel (20), and - a remote control (26), waterproof, adapted to control the movement of the valve (36) between its open and closed positions. 9. Shower according to any one of the preceding claims, wherein the shower (2) comprises a photovoltaic panel (98) and a battery (100) electrically connected to this panel (98) so as to make the shower (2) autonomous in electrical energy.40 10. Shower according to any one of the preceding claims, wherein the shower (2) comprises a box (8), equipped with wheels (105) to facilitate its transport, inside which are housed the tank of clean water (76), the tangential filtration module (72), the clean water pipe (82) connected to the clean water outlet of the filtration module and the clean water tank, and the gray water pipe (80) connected to the gray water inlet.