KR20080074260A - Nozzle of cleaner - Google Patents

Abstract

The present invention relates to a nozzle of a cleaner, and more particularly, to a nozzle of a cleaner in which steam is generated inside. More particularly, the present invention relates to a nozzle of a cleaner that prevents overheating of a heater that heats water to generate steam.

The nozzle of the cleaner according to the present invention includes a steam generator for generating steam by heating water by a heater therein; A first temperature sensor configured to control the power supplied to the heater by sensing a temperature of the heater; And a second temperature sensing unit configured to control the power supplied to the heater by sensing a temperature of the heater higher than a sensing temperature of the first temperature sensing unit.

According to the present invention, the overheating of the heater is prevented, there is an effect that the safety accident and damage to the peripheral parts due to the overheating of the heater is effectively prevented, there is an effect that the reliability of the product is improved.

Description

Nozzle for cleaner

1 is a perspective view of a nozzle of a cleaner according to the present invention.

2 is an exploded perspective view of the nozzle;

3 is a perspective view showing a state in which the cover member is removed from the nozzle.

4 is a bottom view of the base according to the invention.

5 is a perspective view of a mop plate according to the present invention.

6 is an exploded perspective view showing a coupling relationship between the mop plate and the nozzle;

<Explanation of symbols for the main parts of the drawings>

10: base 20: cover member

110: steam generator 118: heater

180: safety device 182: first temperature detection unit

184: second temperature detection unit

The present invention relates to a nozzle of a cleaner, and more particularly, to a nozzle of a cleaner in which steam is generated inside. More particularly, the present invention relates to a nozzle of a cleaner that prevents overheating of a heater that heats water to generate steam.

The vacuum cleaner is a device to reduce human labor by cleaning with the power of a machine. A vacuum cleaner using suction force and a water cleaner that injects water and air at the same time by spraying water, as well as foreign matters on the floor by spraying steam recently. Various types of steam cleaners for removing oil have emerged.

In addition, the nozzle of the steam cleaner is provided with a steam generator for generating steam therein, and is configured to remove foreign substances on the bottom surface by using a steam supplied with a mop attached to the lower side. In addition, a heater is provided inside the steam generator to convert water into steam at high temperature.

As described above, the heater for generating steam continuously increases in temperature when power is supplied, but when the temperature of the heater rises excessively, the nozzle may be damaged.

Therefore, it is necessary to prevent the temperature of the heater from rising above a predetermined temperature in order to prevent damage to the nozzle.

The present invention has been proposed in the background as described above, and an object of the present invention is to propose a nozzle of a cleaner that prevents the temperature of a heater for heating water from rising above a predetermined temperature.

It is also an object of the present invention to propose a nozzle of a cleaner in which damage to a product due to excessive operation of the heater is prevented.

The nozzle of the cleaner according to the present invention for achieving the above object is a steam generator for generating steam by heating water by a heater therein; A first temperature sensor configured to control the power supplied to the heater by sensing a temperature of the heater; And a second temperature sensing unit configured to control the power supplied to the heater by sensing a temperature of the heater higher than a sensing temperature of the first temperature sensing unit.

According to another aspect of the present invention, there is provided a nozzle of a cleaner, comprising: a steam generator provided with a heater to generate steam; A transfer unit to which heat of the heater is transferred; And a plurality of temperature sensing units for measuring the temperature of the transfer unit.

Hereinafter, with reference to the drawings will be described a specific embodiment of the present invention. However, the spirit of the present invention is not limited to the embodiments presented, and those skilled in the art who understand the spirit of the present invention can easily suggest other embodiments within the scope of the same idea.

1 is a perspective view of a nozzle of a cleaner according to the present invention, Figure 2 is an exploded perspective view of the nozzle, Figure 3 is a perspective view showing a state in which the cover member is removed from the nozzle.

1 to 3, the nozzle 1 of the cleaner according to the present invention is a portion for sucking the air containing the dust on the bottom surface and steam is discharged, the base 10 forming the bottom appearance and the The exterior is formed by the cover member 20 coupled to the upper side of the base 10.

In addition, the nozzle 1 is coupled to the connecting pipe 30 for moving the air sucked from the bottom to the cleaner body (not shown) on the rear side, the mop plate 40 is attached to the lower mop 50 is Combined.

In detail, a suction port (see 102 in FIG. 4) is formed at the front end portion of the base 10 to allow foreign substances on the bottom surface to be sucked up. In addition, the suction port (see 102 in FIG. 4) and the connection pipe 30 are connected by the suction flow path pipe 130. The suction flow path tube 130 is formed to extend in the front and rear direction of the nozzle (1).

In addition, the connection pipe 30 may be seated on the rear side of the suction flow path tube 130, and may be rotated up and down with respect to the suction flow path tube 130.

Therefore, the air sucked through the suction port (see 102 of FIG. 4) is introduced into the cleaner body through the suction channel pipe 130 and the connection pipe 30.

On the rear side of the base 10 is provided a moving wheel 140 to enable the movement of the nozzle (1). In addition, a pair of auxiliary wheels (see 142 of FIG. 4) are installed at left and right ends of the base 10 to assist the movement of the nozzle 1.

On the other hand, the base 10 is provided with a steam generator 110 for heating the water to generate steam.

In detail, the steam generating device 110 is provided between the base 10 and the suction passage pipe 130.

The steam generator 110 includes a steam case 112 that forms a space in which water for generating steam is stored, and a heater that generates steam by heating water stored in the steam case 112. 118 is included.

More specifically, the side of the steam case 112 is formed with a plurality of coupling end 112a in the circumferential direction, the base 10 is formed with a plurality of coupling protrusions 103 protruding upward from the inner bottom surface. .

Therefore, as the coupling end 112a of the steam case 112 is coupled with the coupling protrusion 103 of the base 10, the steam generator 110 is primarily coupled to the base 10.

In addition, the screw is fastened to the coupling portion in a state in which the coupling end 112a and the coupling protrusion 103 are coupled so as to completely fix the steam generator 110.

In addition, the steam case 112 is composed of an upper case 113, and a lower case 114 coupled to the upper case 113.

The upper case 114 is provided with a water inlet 115 for introducing water from the outside, the water inlet 115 is an inlet valve in the state that the cover member 20 is coupled to the base 10 It is opened and closed by 60.

In addition, the upper case 113 is formed with a plurality of protrusions 117 forming an additional space to increase the amount of water stored in the steam case 112.

Here, the protrusion 117 is a phenomenon that the water stored in the steam case 112 overflows through the water inlet 115 even when the nozzle 1 is inclined while the water inlet 115 is open. It can also play a role in preventing it.

In addition, the protrusion 117 is to ensure a sufficient space for the steam is formed in the steam case 112.

On the other hand, the heater 118 generates heat by the power applied from the outside, thereby converting the water inside the steam case 112 to steam. In addition, the heater 118 is placed on the steam case 112 in a left and right direction, and is mounted on the steam case 112 in a state in which the heater 118 is coupled to the heater seat 119.

Here, the heater seat 119 serves to not only allow the heater 118 to be seated on the steam case 112, but also to stably fix the heater 118.

In addition, since the heater seat 119 is in close contact with the heater 118 and receives heat from the heater 118, the heater seat 119 is preferably made of a material having heat resistance that can withstand the heat of the heater 118. Do.

In addition, the heater 118 is controlled by the control unit 190 provided on the upper side of the steam generator 110. That is, the heat generation amount, temperature, operating time, etc. of the heater 118 are adjusted by the controller 190.

On the other hand, the heater 118 includes an extension portion 118a extending a portion to the outside of the steam case 112, the heat temperature transmitted from the extension portion 118a on the outside of the steam case 112 The safety device 180 is provided to prevent the heater 118 from overheating by measuring the temperature.

That is, the heater 118 is heated by the power supplied from the outside, when the heater 118 is continuously heated, the peripheral parts are melted or a risk of safety accident occurs. Therefore, in order to prevent the heater 118 from overheating, the safety device 180 is installed.

In detail, the safety device 180 may include at least a first temperature sensing unit 182 that primarily senses a temperature of the extension unit 118a to control power supplied to the heater 118, and the heater ( A second temperature sensing unit 184 for controlling the power supplied to 118 second is included.

In addition, an end portion of the extension part 118a is in contact with a transmission part 170 for transmitting heat of the extension part 118a to each of the temperature sensing parts 182 and 184. Here, the transmission unit 170 is preferably a material having excellent thermal conductivity.

That is, when the heater 118 is operated, heat of the heater 118 is transferred to the transfer unit 170 through the extension unit 118a, and the temperature sensing units 182 and 184 are respectively By sensing the temperature of the delivery unit 170, the heat of the heater 118 is indirectly detected.

In this case, the reason why the transfer unit 170 is provided is to prevent the temperature sensing units 182 and 184 from being damaged by heat transferred directly from the extension unit 118a.

The reason why the temperature sensing units 182 and 184 sense the temperature of the transmission unit 170 is that the temperature sensing units 182 and 184 share the same temperature of the heater 118. In order to sense in the improved reliability, and one extension (118a) is formed to simplify the structure of the heater 118 and the internal structure of the nozzle (1).

The first temperature detector 182 detects whether the temperature of the heater 118 is equal to or greater than a first reference temperature, and the second temperature detector 184 measures the temperature of the heater 118. It is detected whether the temperature rises above the second reference temperature higher than the first reference temperature.

That is, in the present invention, the temperature of the heater 118 is sensed in two steps so that overheating of the temperature of the heater 118 is prevented.

Here, the first temperature sensor 182 may be a thermostat made of bimetal (thermostat). The bimetal is a piece of two kinds of thin metal pieces having very different expansion coefficients, and is generally used. Therefore, a detailed description of the configuration is omitted here.

The first temperature sensing unit 182 made of bimetal has ON / OFF power supplied to the heater 118 when the first reference temperature, for example, about 110 ° C. It is preferably configured to.

That is, when the temperature of the heater 118 becomes high and the temperature transmitted to the first temperature sensing unit 182 is 110 ° C. or higher, the power supplied to the heater 118 is cut off, and at 110 ° C. or lower It is configured to be fed.

The second temperature sensing unit 184 is provided on a power supply line 179 for guiding power to the heater 118, and is preferably configured as a temperature fuse. A thermal fuse is a type of circuit breaker that melts itself by heat and breaks the wire.

The second temperature detector 184 is configured to cut off the power supply to the heater 118 when the temperature of the heater 118 becomes a high temperature and is a second reference temperature, for example, 170 ° C. or more. do. That is, the second temperature sensor 184 is disconnected when the temperature of the heater 118 is 170 ° C., so that the power supplied to the heater 118 is cut off.

The second temperature detector 184 is no longer the temperature of the heater 118 at a predetermined temperature when the first temperature detector 182 malfunctions and the temperature of the heater 118 continuously increases. Ascent is prevented.

Here, since the second temperature sensing unit 184 is configured as a temperature fuse as described above, the transmission unit 170 is formed with a support 172 configured to surround the second temperature sensing unit 184. .

On the other hand, the cover member 20 is coupled to the base 10 by forming the outer appearance of the left and right as well as the front and rear of the nozzle (1).

In addition, a guide hole 202 is formed at the rear side of the cover member 20 to allow the connecting pipe 30 to move. Therefore, the connecting pipe 30 may be adjusted in angle within the range of the space formed by the guide hole 202.

In addition, one side of the cover member 20 is formed so that the valve seating portion 206 in which the inlet valve 60 is seated is recessed downward. In addition, a valve through hole 204 through which the lower end of the inlet valve 60 penetrates is formed in the center portion of the valve seat 206 to penetrate up and down.

Therefore, the inlet valve 60 may be coupled to the water inlet 115 in a state in which the cover member 20 is coupled to the base 10 through the valve through hole 204.

Figure 4 is a bottom view of the base according to the invention, Figure 5 is a perspective view of the mop plate according to the invention, Figure 6 is an exploded perspective view showing a coupling relationship of the mop plate and the nozzle.

4 to 6, the mop plate 40 is coupled to the lower side of the base 10, and the mop 50 is attached to the lower side of the mop plate 40.

In detail, the base seating portion 104 of the base 10 is formed to be recessed upwardly. In addition, the plate seating part 104 is formed in a shape corresponding to the mop plate 40 to seat the mop plate 40.

In addition, a plurality of plate coupling parts 150 protruding downward from the bottom of the base 10 to be coupled to the mop plate 40 seated on the plate seating part 104.

In detail, the plate coupling portion 150 is formed in a cylindrical shape, and at least one pair of engaging grooves 152 are formed. In addition, at least one pair of locking members 420 provided in the mop plate 40 are selectively inserted into the locking groove 152 when the mop plate 40 is coupled to the mop plate 40.

In addition, the steam discharge unit 160 for discharging the steam generated by the steam generator 110 is formed in the center of the base 10 to the left and right.

In detail, a flow path is formed in the steam discharge unit 160 to guide the steam moved downward from the base 10 through the steam discharge pipe 116 to be distributed to the left and right.

In addition, a plurality of steam discharge holes 162 are formed through the bottom of the steam discharge part 160 up and down. Therefore, the steam guided by the steam discharge unit 160 is completely discharged from the nozzle 1 through the steam discharge hole 162, the discharged steam is attached to the lower side of the mop plate 40 The mop 50 is supplied.

On the other hand, the mop plate 40 is selectively seated on the plate seating portion 104.

The mop plate 40 is a plate to which the mop 50 is detachably attached, and a mop attachment part 450 is formed at a bottom thereof so that the mop 50 is detachable.

Here, the mop attachment portion 450 is preferably made of a Velcro (velcro) or a magic tape also referred to as 'sticky'.

In addition, a through hole 410 through which the steam discharge part 160 penetrates is formed in the center of the mop plate 40 to penetrate up and down. In addition, the through hole 410 is formed long in left and right in a size corresponding to the left and right length of the steam discharge unit 160.

Therefore, the bottom surface of the steam discharge part 160 is exposed to the lower portion of the mop plate 40 through the through hole 410. As described above, the steam guide rib 164 protrudes out of the mop plate 40.

Then, at one rear end of the mop plate 40, the removal lever 408 is protruded to a predetermined size to the rear.

The removal lever 408 allows the mop plate 40 to be easily separated from the base 10, and is vertically bent upward from the rear end of the mop plate 40, and then vertically bent backwards. It is shaped as a whole in a '' 'shape (as seen from the left side).

Hereinafter, the operation of the nozzle 1 will be described.

First, when the cleaner body connected to the nozzle 1 is operated, suction force is generated by the suction force generating means provided in the cleaner body, and thus air containing dust on the bottom surface is sucked through the suction port 102. .

In addition, the air sucked through the suction port 102 is moved to the rear of the nozzle 1 along the suction flow path tube 130, and is moved to the cleaner body through the connection pipe 30.

On the other hand, the user can clean the bottom surface using steam as needed.

In order to clean the bottom surface using steam, the user rotates the inlet valve 60 to open the water inlet 115, and then supplies water from the outside through the water inlet 150. When the appropriate amount of water is accommodated in the steam case 112, the water inlet 115 is shielded using the inlet valve 60 again.

Next, when power is applied from the outside, the steam generator 110 is operated by the power. That is, external power is supplied to the heater 118 so that the heater 118 generates heat.

When the heater 118 generates heat, water stored in the steam case 112 is heated to form steam. At this time, the water heated by the heater 118 is not water of the whole stored in the steam case 112, but the water around the heater 118.

In addition, steam generated by the heater 118 flows into the steam discharge unit 160. At this time, since the steam discharge unit 160 is formed long to the left and right, the steam inside the steam discharge unit 160 is distributed to the left and right and discharged downward through the plurality of steam discharge holes 162.

The steam discharged to the outside through the steam discharge hole 162 is supplied to the mop 50. Then, the mop 50 becomes a mop containing hot steam, and when the bottom surface is cleaned in this state, dust attached to the bottom surface is easily separated and removed by the mop 50.

On the other hand, since the safety device 180 is provided on the outside of the steam generating device 110, when the heater 118 is overheated to be above the first reference temperature, the first temperature detection is primarily made of bimetal The power is cut off by the unit 182.

In addition, when the temperature transmitted to the second temperature detection unit 182 due to overheating of the heater 118 does not play a role as the first temperature detection unit 182 becomes greater than or equal to a second reference temperature. The second temperature sensing unit 184 is cut off to cut off the power supplied to the heater 118.

More specifically, when the heater 118 is heated, heat of the heater 118 is conducted to the transfer unit 170 through the extension portion 118a. At this time, it takes a predetermined time until the heat of the heater 118 is transferred to the transfer unit 170.

As a result of the experiment, even when the temperature of the heater 118 reaches 130 ° C by initial heating, the heat of the heater 118 may not be transferred to the transfer unit 170, so that the transfer unit 170 may The temperature is measured around 110 ° C.

Therefore, in the case of initial rapid heating or abnormal overheating, when the temperature of the heater 118 becomes 130 ° C or higher, the temperature of the transmission unit 170 becomes 110 ° C or higher, and the first temperature sensing unit 182 Stops the power supply of the heater 118, and after a predetermined time, when the temperature of the transmission unit 170 falls below 110 ° C, power is supplied to the heater 118 again.

Meanwhile, as the above-described process of selectively shutting off the power supplied to the heater 118 by the first temperature sensor 182 is repeated, the temperature of the heater 118 rises above the first reference temperature. Although the first temperature sensing unit 182 is abnormally operated, the temperature of the heater 118 continues to rise above the first reference temperature.

In this case, the temperature of the transmission unit 170 gradually increases, and the temperature of the second temperature detection unit 184 coupled to the transmission unit 170 increases.

In this case, the second temperature sensing unit 184 made of the thermal fuse is turned off to cut off the power supply to the heater 118. In this case, the second temperature detector 184 may not be repeatedly used as the first temperature detector 182, and thus, the second temperature detector 184 should be replaced.

The scope of the present invention is not limited to the above-exemplified embodiments, and many other modifications based on the present invention will be possible to those skilled in the art within the above technical scope.

For example, in the above embodiment, as a temperature sensing unit for sensing the temperature of the heater 118, a configuration consisting of bimetal and a temperature fuse is illustrated, but other components may be used. Of course, the installation location and quantity can also be used in various ways.

That is, as the temperature sensing unit, any one of bimetal and a temperature fuse may be used, or other components other than bimetal and a temperature fuse may be added.

According to the present invention as proposed, a safety device that can adjust the temperature of the heater in at least two steps to prevent overheating of the heater is provided.

Therefore, there is an effect that the safety accident or damage to the peripheral parts due to overheating of the heater is effectively prevented, and the reliability of the product is improved.

In addition, since the overheating of the heater is prevented by the safety device, there is an effect that can reduce the power consumption due to the overheating of the heater.

Claims (6)

A steam generator for generating steam by heating water by an internal heater; A first temperature sensor configured to control the power supplied to the heater by sensing a temperature of the heater; And And a second temperature sensor configured to sense a temperature of the heater that is higher than a detected temperature of the first temperature detector to control power supplied to the heater. The method of claim 1, An extension part extending from the heater so that heat of the heater located inside the steam generator is transferred to the outside of the steam generator; And a transfer unit configured to transfer heat of the extension unit to each of the temperature sensing units. The method of claim 1, The transfer unit for transmitting the heat of the heater is included, wherein each of the temperature sensing unit nozzle of the cleaner for sensing the temperature of the transfer unit. The method of claim 2 or 3, At least a temperature fuse may be used in the second temperature detector, and the second temperature detector is fixed to the transfer unit. The method of claim 1, The nozzle of the cleaner, wherein each of the temperature sensing units is formed of at least one of a bimetal or a thermal fuse. A steam generator that is provided with a heater to generate steam; A transfer unit to which heat of the heater is transferred; And The nozzle of the cleaner including a plurality of temperature sensing unit for measuring the temperature of the transmission unit.

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